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Sonic Alert msm80154s manuale d’uso - BKManuals

Sonic Alert msm80154s manuale d’uso

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Un buon manuale d’uso

Le regole impongono al rivenditore l'obbligo di fornire all'acquirente, insieme alle merci, il manuale d’uso Sonic Alert msm80154s. La mancanza del manuale d’uso o le informazioni errate fornite al consumatore sono la base di una denuncia in caso di inosservanza del dispositivo con il contratto. Secondo la legge, l’inclusione del manuale d’uso in una forma diversa da quella cartacea è permessa, che viene spesso utilizzato recentemente, includendo una forma grafica o elettronica Sonic Alert msm80154s o video didattici per gli utenti. La condizione è il suo carattere leggibile e comprensibile.

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La parola deriva dal latino "instructio", cioè organizzare. Così, il manuale d’uso Sonic Alert msm80154s descrive le fasi del procedimento. Lo scopo del manuale d’uso è istruire, facilitare lo avviamento, l'uso di attrezzature o l’esecuzione di determinate azioni. Il manuale è una raccolta di informazioni sull'oggetto/servizio, un suggerimento.

Purtroppo, pochi utenti prendono il tempo di leggere il manuale d’uso, e un buono manuale non solo permette di conoscere una serie di funzionalità aggiuntive del dispositivo acquistato, ma anche evitare la maggioranza dei guasti.

Quindi cosa dovrebbe contenere il manuale perfetto?

Innanzitutto, il manuale d’uso Sonic Alert msm80154s dovrebbe contenere:
- informazioni sui dati tecnici del dispositivo Sonic Alert msm80154s
- nome del fabbricante e anno di fabbricazione Sonic Alert msm80154s
- istruzioni per l'uso, la regolazione e la manutenzione delle attrezzature Sonic Alert msm80154s
- segnaletica di sicurezza e certificati che confermano la conformità con le norme pertinenti

Perché non leggiamo i manuali d’uso?

Generalmente questo è dovuto alla mancanza di tempo e certezza per quanto riguarda la funzionalità specifica delle attrezzature acquistate. Purtroppo, la connessione e l’avvio Sonic Alert msm80154s non sono sufficienti. Questo manuale contiene una serie di linee guida per funzionalità specifiche, la sicurezza, metodi di manutenzione (anche i mezzi che dovrebbero essere usati), eventuali difetti Sonic Alert msm80154s e modi per risolvere i problemi più comuni durante l'uso. Infine, il manuale contiene le coordinate del servizio Sonic Alert in assenza dell'efficacia delle soluzioni proposte. Attualmente, i manuali d’uso sotto forma di animazioni interessanti e video didattici che sono migliori che la brochure suscitano un interesse considerevole. Questo tipo di manuale permette all'utente di visualizzare tutto il video didattico senza saltare le specifiche e complicate descrizioni tecniche Sonic Alert msm80154s, come nel caso della versione cartacea.

Perché leggere il manuale d’uso?

Prima di tutto, contiene la risposta sulla struttura, le possibilità del dispositivo Sonic Alert msm80154s, l'uso di vari accessori ed una serie di informazioni per sfruttare totalmente tutte le caratteristiche e servizi.

Dopo l'acquisto di successo di attrezzature/dispositivo, prendere un momento per familiarizzare con tutte le parti del manuale d'uso Sonic Alert msm80154s. Attualmente, sono preparati con cura e tradotti per essere comprensibili non solo per gli utenti, ma per svolgere la loro funzione di base di informazioni e di aiuto.

Sommario del manuale d’uso

  • Pagina 1

    MSM80C154S MSM83C154S MSM85C154HVS USER'S MANU AL[...]

  • Pagina 2

     Copyright 1988, OKI ELECTRIC INDUSTRY COMPANY, LTD. OKI makes no warranty for the use of its products and assumes no responsibility for any errors which may appear in this document nor does it make a commitment to update the information contained herein. OKI retains the right to make changes to these specifications at any time, without notice.[...]

  • Pagina 3

    CONTENTS 1. INTRODUCTION 1.1 MSM80C154S/MSM83C154S/MSM85C154HVS Outline .................................. 3 1.2 MSM80C154S/MSM83C154S Features ............................................................. 5 1.3 Additional Features in MSM80C154S/MSM83C154S/MSM85C154HVS ........... 7 2. SYSTEM CONFIGURATION 2.1 MSM80C154S/MSM83C154S/MSM85C154HVS Log[...]

  • Pagina 4

    3. CONTROL 3.1 Oscillators [XTAL1 .2] ....................................................................................... 43 3.2 CPU Resetting .................................................................................................. 45 3.2.1 Outline .......................................................................................[...]

  • Pagina 5

    4.5.2.5.7 Caution about use of timer counters 0 and 1 .................................. 90 4.5.2.5.8 Caution about use of timer counters 0 and 1 when setting software power down mode ........................................................................... 91 4.5.3 Timer/counter 2 .................................................................[...]

  • Pagina 6

    4.6.4.2 Multi-processor systems ...................................................................... 128 4.7 Interrupt ............................................................................................................. 129 4.7.1 Outline .....................................................................................................[...]

  • Pagina 7

    5.7 High Impedance Input Port Setting of Each Quasi-bidirectional Port 1, 2, and 3 ............................................................................................... 207 5.8 100 k W Pull-Up Resistance Setting for Quasi-bidirectional Input Ports 1, 2, and 3 ................................................................................[...]

  • Pagina 8

    1. INTR ODUCTION[...]

  • Pagina 9

    MSM80C154S/83C154S/85C154HVS 2[...]

  • Pagina 10

    INTRODUCTION 3 1. INTRODUCTION 1.1 MSM80C154S/MSM83C154S/MSM85C154HVS Outline MSM80C154S/MSM83C154S/MSM85C154HVS are single-chip 8-bit fully static microcon- trollers featuring high performance and low power consumption. All MSM80C31F /MSM80C51F instructions and functions have been retained. Apart from being without the internal program memory (ROM[...]

  • Pagina 11

    MSM80C154S/83C154S/85C154HVS 4 execution from the next address after the stop address where CPU power down mode was activated. Each of the quasi-bidirectional ports 1, 2, and 3 can be set independently as high impedance input ports. And the 10 k W pull-up resistance for these input ports can be isolated from the power supply (V CC ), leaving only t[...]

  • Pagina 12

    INTRODUCTION 5 1.2 MSM80C154S/MSM83C154S Features • Full static circuitry • Internal program memory (ROM) 16384 words × 8 bits (MSM83C154S) • External program memory (ROM) Connectable up to 64K bytes • Internal data memory (RAM) 256 words × 8 bits • External data memory (RAM) Connectable up to 64K bytes • Four sets of working register[...]

  • Pagina 13

    MSM80C154S/83C154S/85C154HVS 6 • Timer/counters (three 16-bit timer/counters) (1) 8-bit timer with 5-bit prescalar (2) 16-bit timer (3) 8-bit timer with 8-bit auto-reloader (4) 8-bit separate timer (5) 16-bit timer with 16-bit auto-reloader (6) 16-bit capture timer (7) 16-bit baud rate generator timer (8) 32-bit timer • Wide operating temperatu[...]

  • Pagina 14

    INTRODUCTION 7 1.3 Additional Features in MSM80C154S/MSM83C154S/MSM85C154HVS In addition to the basic operations of MSM80C31F/MSM80C51F, the MSM80C154S/ MSM83C154S/MSM85C154HVS devices also include the following functions. • ROM capacity increased from 4K bytes to 16K bytes • RAM capacity increased from 128 bytes to 256 bytes • An additional [...]

  • Pagina 15

    MSM80C154S/83C154S/85C154HVS 8[...]

  • Pagina 16

    2. SYSTEM CONFIGURA TION[...]

  • Pagina 17

    MSM80C154S/83C154S/85C154HVS 10[...]

  • Pagina 18

    SYSTEM CONFIGURATION 11 2. SYSTEM CONFIGURATION 2.1 MSM80C154S/MSM83C154S/MSM85C154HVS Logic Symbols P0.0 P0.1 P0.2 P0.3 P0.4 P0.5 P0.6 P0.7 P1.0 P1.1 P1.2 P1.3 P1.4 P1.5 P1.6 P1.7 P2.0 P2.1 P2.2 P2.3 P2.4 P2.5 P2.6 P2.7 P3.0 P3.1 P3.2 P3.3 P3.4 P3.5 P3.6 P3.7 T2 T2EX RXD TXD INT 0 INT 1 T0 T1/HPDI WR RD PORT 0 (BUS PORT) PORT 1 PORT 2 PORT 3 XTAL1[...]

  • Pagina 19

    MSM80C154S/83C154S/85C154HVS 12 2.2 MSM80C154S/MSM83C154S pin layouts 1 P1.0/T2 2 P1.1/T2EX 3 P1.2 4 P1.3 5 P1.4 6 P1.5 7 P1.6 8 P1.7 9 RESET 10 P3.0/RXD 11 P3.1/TXD 12 P3.2/ INT 0 13 P3.3/ INT 1 14 P3.4/T0 15 P3.5/T1/HPDI 16 P3.6/ WR 17 P3.7/ RD 18 XTAL2 19 XTAL1 20 V SS 40 V CC 39 P0.0 38 P0.1 37 P0.2 36 P0.3 35 P0.4 34 P0.5 33 P0.6 32 P0.7 31 EA[...]

  • Pagina 20

    SYSTEM CONFIGURATION 13 7 P1.5 8 P1.6 9 P1.7 10 RESET 11 P3.0/RXD 12 NC 13 P3.1/TXD 14 P3.2/ INT 0 15 P3.3/ INT 1 16 P3.4/T0 17 P3.5/T1/HPDI MSM80C154SJS/MSM83C154SJS MSM80C154SJS/MSM83C154SJS (Top View) 44 Pin Plastic QFJ P3.6/ WR P3.7/ RD XTAL2 XTAL1 V SS NC P2.0 P2.1 P2.2 P2.3 P2.4 P1.4 P1.3 P1.2 P1.1/T2EX P1.0/T2 NC V CC P0.0 P0.1 P0.2 P0.3 39 [...]

  • Pagina 21

    MSM80C154S/83C154S/85C154HVS 14 Applicable Packages 40-Pin Plastic DIP (DIP40-P-600-2.54) 44-Pin Plastic QFJ (QFJ44-P-S650-1.27) 44-Pin Plastic QFP (DFP44-P-910-0.80-2K) 44-Pin Plastic TQFP (TQFP44-P-1010-0.80-K) 40-Pin Ceramic Piggy Back (ADIP40-C-600-2.54) MSM80C154S RS MSM83C154S-XXX RS MSM80C154S JS MSM83C154S-XXX JS MSM80C154S GS-2K MSM83C154S[...]

  • Pagina 22

    SYSTEM CONFIGURATION 15 2.2.1 MSM80C154S/MSM83C154S external dimensions Figure 2-3 MSM80C154S/MSM83C154S external dimensions MSM80C154SRS/MSM83C154SRS 40-pin Plastic DIP (DIP40-P-600-2.54) MSM80C154SJS/MSM83C154SJS 44-Pin Plastic QFJ (QFJ44-P-S650-1.27) MSM80C154SGS/MSM83C154SGS 44-Pin Plastic QFP (QFP44-P-910-0.80-2K)[...]

  • Pagina 23

    MSM80C154S/83C154S/85C154HVS 16 MSM80C154STS/MSM83C154STS 44-Pin Plastic TQFP (TQFP44-P-1010-0.80-K)[...]

  • Pagina 24

    SYSTEM CONFIGURATION 17 2.2.2 MSM85C154HVS pin layout and external dimensions * The MSM85C154HVS pin layout of bottom side is the same as the pin layout for MSM83C154SRS. * The 27C64/128 device should be used for EPROM. M85C154H OKI JAPAN XXXX 2764/27128 Pin 1 for 2764, 27128 Figure 2-4 MSM85C154HVS pin layout and external dimensions 40-Pin Ceramic[...]

  • Pagina 25

    MSM80C154S/83C154S/85C154HVS 18 2.3 MSM80C154S Block Diagram 256WORD × 8bit TH1 PORT 2 P2.0 P2.7 PORT 0 P0.0 P0.7 PCON IOCON OSC AND TIMING XTAL1 XTAL2 ALE PSEN EA RESET PORT 1 P1.0 P1.7 PORT 3 P3.0 P3.7 TL1 TH0 TL0 TMOD TCON IE IP SCON TIMER/COUNTER 0&1 INTERRUPT SERIAL IO SBUF (T) SBUF (R) T2CON TL2 TIMER/ COUNTER 2 PCH TH2 RCAP 2L RCAP 2H P[...]

  • Pagina 26

    SYSTEM CONFIGURATION 19 2.4 MSM83C154S Block Diagram TH1 P2.0 P2.7 P0.0 P0.7 XTAL1 XTAL2 ALE PSEN EA RESET P1.0 P1.7 P3.0 P3.7 TL1 TH0 TL0 TMOD TCON IE IP SCON TIMER/COUNTER 0&1 INTERRUPT SERIAL IO SBUF (T) SBUF (R) T2CON TL2 TIMER/ COUNTER 2 PCH TH2 RCAP 2L RCAP 2H PCL PCHL PCLL R/W AMP 256WORD × 8bit RAMDP PSW ACC TR2 TR1 BR ALU IR AIR C-ROM[...]

  • Pagina 27

    MSM80C154S/83C154S/85C154HVS 20 2.5 MSM85C154HVS Block Diagram TH1 P2.0 P2.7 P0.0 P0.7 XTAL1 XTAL2 ALE PSEN EA RESET P1.0 P1.7 P3.0 P3.7 TL1 TH0 TL0 TMOD TCON IE IP SCON TIMER/COUNTER 0&1 INTERRUPT SERIAL IO SBUF (T) SBUF (R) T2CON TL2 TIMER/ COUNTER 2 PCH TH2 RCAP 2L RCAP 2H PCL PCHL PCLL R/W AMP 256WORD × 8bit RAMDP PSW ACC TR2 TR1 BR ALU IR[...]

  • Pagina 28

    SYSTEM CONFIGURATION 21 2.6 Timing and Control 2.6.1 Outline of MSM80C154S/MSM83C154S timing The MSM80C154S/MSM83C154S devices are both equipped with a built-in oscillation inverter (see Figure 2-8) for use in the generation of clock pulses by external crystal or ceramic resonator. These clock pulses are passed to the timing counter and control cir[...]

  • Pagina 29

    MSM80C154S/83C154S/85C154HVS 22 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 S2 S3 S4 S5 S6 M1 PCL PCL PCL PCL PCL PCL ACC & RAM DPL & Rr PCH PCH PCH PCH DPH & PORT DATA PCH PCH PCH DATA STABLE DATA STABLE PORT OLD DATA PORT NEW DATA Instruction decoding Instruction excecution PC+1 PC+1 TM+1 Instruction decoding Ins[...]

  • Pagina 30

    SYSTEM CONFIGURATION 23 2.6.2 Major synchronizing signals (1) ALE (Address Latch Enable) The ALE signal is used as a clock signal where the address signals 0 thru 7 output from CPU port 0 can be latched externally when external program or external data memory (RAM) is used. Although two ALE signal outputs are obtained in a single machine cycle duri[...]

  • Pagina 31

    MSM80C154S/83C154S/85C154HVS 24 2.6.3 MSM80C154S fundamental operation time charts S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 or M2 S1 PCL OUT INST IN PCH OUT PCH OUT PCH OUT PCH OUT XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT–0 1 0 PORT–2 1 0 PCH OUT PCL OUT INST IN PCL OUT INST IN PCL OUT INST IN INST IN S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 PCL OU[...]

  • Pagina 32

    SYSTEM CONFIGURATION 25 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 PCL OUT INST IN PCH OUT PCH OUT PORT 2 LATCH DATA OUT XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT–0 1 0 PORT–2 1 0 PCH OUT Rr OUT ACC DATA OUT PCL OUT INST IN WR 1 0 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 PCL OUT INST IN PCH OUT PCH OUT DPH OUT XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT–0 1 [...]

  • Pagina 33

    MSM80C154S/83C154S/85C154HVS 26 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 PCL OUT INST IN PCH OUT PCH OUT DPH OUT XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT–0 1 0 PORT–2 1 0 PCH OUT DPL OUT ACC DATA OUT PCL OUT INST IN WR 1 0 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0,1,2,3 PIN DATA 1 0 CPU DATA SAMPLED 1 0 PIN DATA [...]

  • Pagina 34

    SYSTEM CONFIGURATION 27 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 PORT 0 LATCH DATA XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT–0 1 0 PORT–2 1 0 Rr OUT EXT RAM DATA FLOATING RD 1 0 PORT 2 LATCH DATA OUT RAM DATA IN S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 PORT 0 LATCH DATA XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT–0 1 0 PORT–2 1 0 Rr OUT ACC DATA OUT FLOA[...]

  • Pagina 35

    MSM80C154S/83C154S/85C154HVS 28 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 PORT 0 LATCH DATA XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT–0 1 0 PORT–2 1 0 DPL OUT EXT RAM DATA FLOATING RD 1 0 RAM DATA IN PORT 2 LATCH DATA OUT DPH OUT PORT 2 LATCH DATA OUT S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 PORT 2 LATCH DATA OUT DPH OUT PORT 2 LATCH DATA OUT S1 PORT[...]

  • Pagina 36

    SYSTEM CONFIGURATION 29 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0,1,2,3 PIN DATA 1 0 CPU DATA SAMPLED 1 0 PIN DATA STABLE Figure 2-20 MSM83C154S MOV direct, PORT[0, 1, 2, 3] execution (5) MOV direct, PORT [0, 1, 2, 3] execution[...]

  • Pagina 37

    MSM80C154S/83C154S/85C154HVS 30 2.7 Instruction Register (IR) and Instruction Decoder (PLA) MSM80C154S/MSM83C154S operations are based on an instruction code address method. Hence, in addition to the instruction code instruction register (IR) and instruction decoder (PLA), these devices also include an instruction register (AIR) and register manipu[...]

  • Pagina 38

    SYSTEM CONFIGURATION 31 2.8 Arithmetic Operation Section (1) Outline The MSM80C154S/MSM83C154S arithmetic operation section consists of (1) an arithmetic operation instruction decoder, and (2) an arithmetic and logic unit [ALU]. (2) Arithmetic operation instruction decoder: Arithmetic operation instructions are passed to the instruction register (I[...]

  • Pagina 39

    MSM80C154S/83C154S/85C154HVS 32 2.9 Program Counter The MSM80C154S/MSM83C154S program counter has a 16-bit configuration PC 0 thru PC 15 , as shown in Figure 2-23. Q8 Q9 Q10 Q11 Q12 Q13 Q14 Q15 D8 D9 D10 D11 D12 D13 D14 D15 Q0 Q1 Q2 Q3 Q4 Q5 Q6 Q7 D0 D1 D2 D3 D4 D5 D6 D7 PC+1 MSM83C154S INTERNAL ROM 16KWORD × 8BIT CPU INTERNAL DATA BUS EXTERNAL RO[...]

  • Pagina 40

    SYSTEM CONFIGURATION 33 2.10 Program Memory and External Data Memory 2.10.1 MSM80C154S/MSM83C154S program area and external ROM connections Since MSM80C154S/MSM83C154S are equipped with a 16-bit program counter, these devices can execute programs of up to 64K bytes (including both internal and external programs). Since the MSM80C154S is not equippe[...]

  • Pagina 41

    MSM80C154S/83C154S/85C154HVS 34 D0 D1 D2 D3 D4 D5 D6 D7 Q0 Q1 Q2 Q3 Q4 Q5 Q6 Q7 MSM74HC373 LATCH P0.0 P0.1 P0.2 P0.3 P0.4 P0.5 P0.6 P0.7 ALE P2.0 P2.1 P2.2 P2.3 P2.4 P2.5 P2.6 P2.7 PSEN MSM80C154S/MSM83C154S A0 A1 A2 A3 A4 A5 A6 A7 A8 A9 A10 A11 A12 A13 A14 A15 OUTPUT ENABLE CS Q7 Q6 Q5 Q4 Q3 Q2 Q1 Q0 ROM 64kW × 8BIT Figure 2-25 MSM80C154S/MSM83C1[...]

  • Pagina 42

    SYSTEM CONFIGURATION 35 2.10.2 Procedures and circuit connections used when external data memory (RAM) is accessed by data pointer (DPTR) The MSM80C154S/MSM83C154S can be connected to an external 64K word × 8-bit data memory (RAM) when accessing the memory by data pointer (DPTR). The data pointer (DPTR) consists of DPL and DPH registers. The DPL r[...]

  • Pagina 43

    MSM80C154S/83C154S/85C154HVS 36 D0 D1 D2 D3 D4 D5 D6 D7 Q0 Q1 Q2 Q3 Q4 Q5 Q6 Q7 MSM74HC373 LATCH P0.0 P0.1 P0.2 P0.3 P0.4 P0.5 P0.6 P0.7 ALE P2.0 P2.1 P2.2 P2.3 P2.4 P2.5 P2.6 P2.7 RD MSM80C154S/MSM83C154S A0 A1 A2 A3 A4 A5 A6 A7 A8 A9 A10 A11 A12 A13 A14 A15 CS R/ W 7 6 5 4 3 2 1 0 ROM 64kW × 8BIT I/O WR Figure 2-26 Connection circuit for externa[...]

  • Pagina 44

    SYSTEM CONFIGURATION 37 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 S2 S3 S4 S5 S6 M1 PCL PCL PCL PCL PCL PCL ACC DATA DPL INSTRUCTION IN PCH PCH PCH PCH DPH PCH PCH PCH XTAL1 1 0 ALE 1 0 PSEN 1 0 WR 1 0 PORT–0 1 0 PORT–2 1 0 S6 PCL MOVX @DPTR, A S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 S2 S3 S4 S5[...]

  • Pagina 45

    MSM80C154S/83C154S/85C154HVS 38 2.10.3 Procedures and circuit connections used when external data memory (RAM) is accessed by registers R0 and R1 The MSM80C154S/MSM83C154S can be connected to an external 256 word ¥ 8-bit data memory (RAM) when addressing the memory according to the contents of registers R0 and R1 in the internal data memory (RAM).[...]

  • Pagina 46

    SYSTEM CONFIGURATION 39 D0 D1 D2 D3 D4 D5 D6 D7 Q0 Q1 Q2 Q3 Q4 Q5 Q6 Q7 MSM74HC373 LATCH P0.0 P0.1 P0.2 P0.3 P0.4 P0.5 P0.6 P0.7 ALE RD MSM80C154S/MSM83C154S A0 A1 A2 A3 A4 A5 A6 A7 CS R/ W 7 6 5 4 3 2 1 0 ROM 256W × 8BIT I/O WR Figure 2-28 Connection circuit for external data memory addressed by register R0 or R1[...]

  • Pagina 47

    MSM80C154S/83C154S/85C154HVS 40 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 S2 S3 S4 S5 S6 M1 PCL PCL PCL PCL PCL PCL ACC DATA Rr INSTRUCTION IN PCH PCH PCH PCH PORT 2 LATCH DATA PCH PCH PCH XTAL1 1 0 ALE 1 0 PSEN 1 0 WR 1 0 PORT–0 1 0 PORT–2 1 0 S6 PCL MOVX @Rr, A S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S[...]

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    3. CONTR OL[...]

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    MSM80C154S/83C154S/85C154HVS 42[...]

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    CONTROL 43 3. CONTROL 3.1 Oscillators: XTAL1 XTAL2 An oscillator is formed by connecting a crystal or ceramic resonator between the XTAL1 and XTAL2 pins of the MSM80C154S/MSM83C154S devices. If an external clock is applied to XTAL1, the input should be at 50% duty and C-MOS level. IDLE MODE PD & HPD MODE CPU CONTROL CLOCK TIMER, S I/O & INT[...]

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    MSM80C154S/83C154S/85C154HVS 44 IDLE MODE PD & HPD MODE CPU CONTROL CLOCK TIMER, S I/O & INTERRUPT 1M Ω XTAL1 XTAL2 C C * * MSM80C154S/MSM83C154S * The capacity of the compensating capacitor depends on the ceramic resonator. * The XTAL1·2 frequency depends on V CC . Figure 3-2 Ceramic resonator connection diagram IDLE MODE PD & HPD M[...]

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    CONTROL 45 3.2 CPU Resetting 3.2.1 Outline If a reset signal (kept at “1” level for at least 1 µ sec) is applied to the RESET pin when the correct voltage (in respect to the various specifications) is applied to the MSM80C154S/ MSM83C154S V CC pin, a reset signal is stored in the CPU even if the XTAL1·2 oscillators have been stopped. The inte[...]

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    MSM80C154S/83C154S/85C154HVS 46 Figure 3-5 Reset execution time chart (internal ROM mode) S1 S2 S3 S4 S5 S6 M1 or M2 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 S2 S3 S4 S5 S6 M1 PORT DATA XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 RESET 1 0 PORT DATA PORT DATA PORT DATA CPU RESET CONTROL 1 0 RESET EXCECUTE 1 0 FLOATING[...]

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    CONTROL 47 Figure 3-6 Reset execution time chart (external ROM mode) S1 S2 S3 S4 S5 S6 M1 or M2 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 RESET 1 0 CPU RESET CONTROL 1 0 RESET EXCECUTE 1 0 PORT DATA = 1 PORT DATA = 1 PORT DATA = 1 CPU RESET EXCECUTE CYCLE S6[...]

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    MSM80C154S/83C154S/85C154HVS 48 Figure 3-7 Reset release time chart (internal ROM mode) S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 RESET 1 0 CPU RESET CONTROL 1 0 RESET EXCECUTE 1 0 FLOATING PORT DATA = 1 PORT DATA = 1 PORT DATA = 1 CPU RESE[...]

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    CONTROL 49 Figure 3-8 Reset release time chart (external ROM mode) S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 RESET 1 0 CPU RESET CONTROL 1 0 RESET EXCECUTE 1 0 PORT DATA = 1 S6 FLOATING PCL PCL PCL PCH PCH PCH CPU RESET EXCECUTE CYCLE PORT [...]

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    MSM80C154S/83C154S/85C154HVS 50 3.2.2 Reset Schmitt trigger circuit The Schmitt trigger circuit connected to the RESET pin shown in the MSM80C154S/ MSM- 83C154S reset circuit block diagram in Figure 3-4 operates in the following way when the V CC power supply voltage is +5V. If the voltage of the reset signal applied to the RESET pin exceeds 3V whe[...]

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    CONTROL 51 3.2.3 CPU internal status by reset When a reset signal is applied to the CPU with normal voltage applied to the MSM80C154S/ MSM83C154S V CC power supply pin, ports 0, 1, 2, and 3 are set to “1” (input mode) even if XTAL1·2 oscillation has been stopped. The output status of the ALE and PSEN pins also becomes “1”. The CPU is then [...]

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    MSM80C154S/83C154S/85C154HVS 52 3.3 EA (CPU Memory Separate) 3.3.1 Outline The function of the EA pin is to determine whether a CPU internal program memory (ROM) instruction or an external program instruction is to be executed. (1) Internal ROM mode If the EA pin is connected to V CC and a “1” reset signal is applied to the RESET pin to reset t[...]

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    4. INTERNAL SPECIFICA TIONS[...]

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    MSM80C154S/83C154S/85C154HVS 54[...]

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    INTERNAL SPECIFICATIONS 55 4. INTERNAL SPECIFICATIONS 4.1 Internal Data Memory (RAM) and Special Function Registers 4.1.1 Outline MSM80C154S/MSM83C154S operation is based on an instruction code address method where operations are specified in an instruction code (OP) section, and the data memory (RAM) and special function registers (ACC, B, TCON, P[...]

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    MSM80C154S/83C154S/85C154HVS 56 IOCON B ACC PSW TH2 TL2 RCAP2H RCAP2L T2CON IP P3 IE P2 SBUF SCON P1 TH1 TH0 TL1 TL0 TMOD TCON PCON DPH DPL SP P0 0FFH~0F8H 0F7H~0F0H 0E7H~0E0H 0D7H~0D0H 0CFH~0C8H 0BFH~0B8H 0B7H~0B0H 0AFH~0A8H 0A7H~0A0H 9FH~98H 97H~90H 8FH~88H 87H~80H 248 (0F8H) 240 (0F0H) 224 (0E0H) 208 (0D0H) 205 (0CDH) 204 (0CCH) 203 (0CBH) 202 ([...]

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    INTERNAL SPECIFICATIONS 57 4.2 Internal Data Memory (RAM) 4.2.1 Internal data memory (RAM) The storage capacity of the MSM80C154S/MSM83C154S data memory is 256 words ¥ 8 bits. The layout diagram is shown in Figure 4-2. The data memory can be accessed (R/W) in four different ways - direct register designation, indirect register designation, data ad[...]

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    MSM80C154S/83C154S/85C154HVS 58 BANK 3 BANK 2 BANK 1 BANK 0 USER DATA RAM USER DATA RAM 7F 7E 7D 7C 7B 7A 79 78 77 76 75 74 73 72 71 70 6F 6E 6D 6C 6B 6A 69 68 67 66 65 64 63 62 61 60 5F 5E 5D 5C 5B 5A 59 58 57 56 55 54 53 52 51 50 4F 4E 4D 4C 4B 4A 49 48 47 46 45 44 43 42 41 40 3F 3E 3D 3C 3B 3A 39 38 37 36 35 34 33 32 31 30 2F 2E 2D 2C 2B 2A 29 2[...]

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    INTERNAL SPECIFICATIONS 59 4.2.2 Internal data memory registers R0 thru R7 Four banks of registers group exist in the data memory (RAM) between memory addresses 00 thru 1FH. Banks are specified by RS0 and RS1 bit combinations within the program status word (PSW). Note that the register area R0 thru R7 can also be used as normal data memory. The PSW[...]

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    MSM80C154S/83C154S/85C154HVS 60 4.2.3 Stack The stack data save (storage) area is in the internal data memory (RAM), and is specified by stack pointer (SP 81H). Although 07H data is automatically set in the stack pointer when the CPU is reset, any desired data can be set by software to enable the data memory to be used as stack from any address. Tw[...]

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    INTERNAL SPECIFICATIONS 61 4.3 lnternal Data Memory (RAM) Operating Procedures 4.3.1 Internal data memory indirect addressing Operation of the internal data memory indirect increment instruction is described here as an example. This instruction (INC @Rr) is a 1-byte 1-machine cycle instruction (see Figure 4- 4). The indirect address register is spe[...]

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    MSM80C154S/83C154S/85C154HVS 62 4.3.2 Internal data memory register R0 thru R7 designation Operation of the internal data memory register decrement instruction is described here as an example. This instruction (DEC Rr) is a 1-byte 1-machine cycle instruction (see Figure 4-5). Register R0 thru R7 is specified by r 0 , r 1 , and r 2 data of instructi[...]

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    INTERNAL SPECIFICATIONS 63 4.3.3 Internal data memory 1-bit data designation In the MSM80C154S/MSM83C154S, 1-bit data manipulations (test, reset, set, complement, transfer) can be executed directly between internal data memory addresses 20 thru 2FH by bit manipulation instructions. The operation of a bit reset instruction is described below as an e[...]

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    MSM80C154S/83C154S/85C154HVS 64 Table 4-4 Bit designation table Bit name Bit 0 Bit 1 Bit 2 Bit 3 Bit 4 Bit 5 Bit 6 Bit 7 b 2 b 1 b 0 000 001 010 011 100 101 110 111 Table 4-5 Addressing combination table b 7 b 6 b 5 b 4 b 3 RAM address 000000 2 0 H 3 2 100001 2 1 H 3 3 200010 2 2 H 3 4 300011 2 3 H 3 5 400100 2 4 H 3 6 500101 2 5 H 3 7 600110 2 6 H[...]

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    INTERNAL SPECIFICATIONS 65 4.4 Special Function Registers (TCON, SCON,.... ACC, B) 4.4.1 Outline As can be seen from the configuration shown in Table 4-6, the MSM80C154S/ MSM83C154S special function registers consist of 27 8-bit registers. Special function registers can be accessed (R/W) by either data addressing or bit addressing. All 27 registers[...]

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    MSM80C154S/83C154S/85C154HVS 66 Table 4-6 List of special function registers b 7 b 6 b 5 b 4 b 3 b 2 b 1 b 0 FF FE FD FC FB FA F9 F8 F7 F6 F5 F4 F3 F2 F1 F0 E7 E6 E5 E4 E3 E2 E1 E0 D7 D6 D5 D4 D3 D2 D1 D0 CF CE CD CC CB CA C9 C8 BF BE BD BC BB BA B9 B8 B7 B6 B5 B4 B3 B2 B1 B0 AF AE AD AC AB AA A9 A8 A7 A6 A5 A4 A3 A2 A1 A0 9F 9E 9D 9C 9B 9A 99 98 9[...]

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    INTERNAL SPECIFICATIONS 67 4.4.2 Special function registers 4.4.2.1 Timer mode register (TMOD) TMOD 89H GATE C/ T M1 M0 GATE C/ T M1 M0 Name Address MSB LSB 76543210 Bit location Flag Function TMOD.0 TMOD.1 TMOD.2 TMOD.3 TMOD.4 TMOD.5 TMOD.6 TMOD.7 M0 M1 C/ T GATE M0 M1 C/ T GATE Timer/counter 0 mode setting 8-bit timer/counter with 5-bit prescalar[...]

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    MSM80C154S/83C154S/85C154HVS 68 4.4.2.2 Power control register (PCON) PCON 87H SMOD HPD RPD — GF1 GF0 PD IDL Name Address MSB LSB 76543210 Bit location Flag Function PCON.0 PCON.1 PCON.2 PCON.3 PCON.4 PCON.5 PCON.6 PCON.7 IDL PD GF0 GF1 — RPD HPD SMOD IDLE mode set when this bit is set to "1". CPU operations are stopped when IDLE mode[...]

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    INTERNAL SPECIFICATIONS 69 4.4.2.3 Timer control register (TCON) TCON 88H TF1 TR1 TF0 TR0 IE1 IT1 IE0 IT0 Name Address MSB LSB 76543210 Bit location Flag Function TCON.0 TCON.1 TCON.2 TCON.3 TCON.4 TCON.5 TCON.6 TCON.7 IT0 IE0 IT1 IE1 TR0 TF0 TR1 TF1 External interrupt 0 signal used in level detect mode when this bit is "0", and in trigge[...]

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    MSM80C154S/83C154S/85C154HVS 70 4.4.2.4 Serial port control register (SCON) SCON 98H SM0 SM1 SM2 REN TB8 RB8 TI RI Name Address MSB LSB 76543210 Bit location Flag Function SCON.0 SCON.1 SCON.2 SCON.3 SCON.4 SCON.5 SCON.6 SCON.7 RI TI RB8 TB8 REN SM2 SM1 SM0 "End of serial port reception" interrupt request flag. This flag must be reset by [...]

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    INTERNAL SPECIFICATIONS 71 4.4.2.5 Interrupt enable register (IE) IE 0A8H EA — ET2 ES ET1 EX1 ET0 EX0 Name Address MSB LSB 76543210 Bit location Flag Function IE.0 IE.1 IE.2 IE.3 IE.4 IE.5 IE.6 IE.7 EX0 ET0 EX1 ET1 ES ET2 — EA Interrupt control bit for external interrupt 0. Interrupt disabled when bit is "0". Interrupt enabled when bi[...]

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    MSM80C154S/83C154S/85C154HVS 72 4.4.2.6 Interrupt priority register (IP) IP 0B8H PCT — PT2 PS PT1 PX1 PT0 PX0 Name Address MSB LSB 76543210 Bit location Flag Function IP.0 IP.1 IP.2 IP.3 IP.4 IP.5 IP.6 IP.7 PX0 PT0 PX1 PT1 PS PT2 — PCT Interrupt priority bit for external interrupt 0. Priority is assigned when bit is "1". Interrupt pri[...]

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    INTERNAL SPECIFICATIONS 73 4.4.2.7 Program status word register (PSW) PSW 0D0H CY AC F0 RS1 RS0 OV F1 P Name Address MSB LSB 76543210 Bit location Flag Function PSW.0 PSW.1 PSW.2 PSW.3 PSW.4 PSW.5 PSW.6 PSW.7 P F1 OV RS0 RS1 F0 AC CY Accumulator (ACC) parity indicator. "1" when the "1" bit number in the accumulator is an odd num[...]

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    MSM80C154S/83C154S/85C154HVS 74 4.4.2.8 I/O control register (IOCON) IOCON 0F8H — T32 SERR IZC P3HZ P2HZ P1HZ ALF Name Address MSB LSB 76543210 Bit location Flag Function IOCON.0 IOCON.1 IOCON.2 IOCON.3 IOCON.4 IOCON.5 IOCON.6 IOCON.7 ALF P1HZ P2HZ P3HZ IZC SERR T32 — If CPU power down mode (PD, HPD) is activated with this bit set to "1&qu[...]

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    INTERNAL SPECIFICATIONS 75 4.4.2.9 Timer 2 control register (T2CON) TMOD 0C8H TF2 EXF2 RCLK TCLK EXEN2 TR2 C/ T2 CP/ RL2 Name Address MSB LSB 76543210 Bit location Flag Function T2CON.0 T2CON.1 T2CON.2 T2CON.3 T2CON.4 T2CON.5 T2CON.6 T2CON.7 CP/ RL2 C/ T2 TR2 EXEN2 TCLK RCLK EXF2 TF2 Capture mode is set when TCLK+RCLK="0" and CP/ RL2 16-b[...]

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    MSM80C154S/83C154S/85C154HVS 76 4.5 Timer/Counters 0, 1 and 2 4.5.1 Outline Timer/counters 0, 1 and 2 are all equipped with 16-bit binary up-counting and Read/Write functions, and can be operated independently. All control of timer/counters 0 and 1 is handled by the timer control register (TCON 88H) and the timer mode register (TMOD 89H). And both [...]

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    INTERNAL SPECIFICATIONS 77 Figure 4-7 Overall clock input control circuit for timer/counters 0 and 1 TIMER 1 GATE C/ T M1 M0 GATE C/ T M1 M0 76543210 TIMER MODE REGISTER (TMOD) TF1 TR1 TF0 TR0 IE1 IT1 IE0 IT0 76543210 TIMER CONTROL REGISTER (TCON) TIMER 0 DETECTOR T1 PIN (PORT 3.5) DATA INT 1 PIN (PORT 3.3) LATCH S5 DETECTOR T0 PIN (PORT 3.4) DATA [...]

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    MSM80C154S/83C154S/85C154HVS 78 4.5.2.3 Timer/counter 0 and 1 count clock designation Designation of count clock inputs to timer/counters 0 and 1 is controlled by bit 2 and 6, C/ T , in the timer mode register (TMOD 89H). Timer/counter 0 is controlled by bit 2, C/ T , and timer/counter 1 is controlled by bit 6, C/ T . The internal clock is passed t[...]

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    INTERNAL SPECIFICATIONS 79 4.5.2.3.1 External clock detector circuit for timer/counters 0 and 1 The detector circuit shown in Figure 4-8 is inserted between the timer/counters and the external clock pin. This detector circuit operates in the following way. When the external clock applied to the T0 and T1 pins is changed from “1” to “0” leve[...]

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    MSM80C154S/83C154S/85C154HVS 80 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 or M2 S1 XTAL1 1 0 ALE 1 0 T0 or T1 COUNT IN 1 0 F/F2Q 1 0 TIMER COUNT 1 0 F/F1Q 1 0 S2 S6 Figure 4-9 Detector circuit operational time chart 4.5.2.4 Counting control of timer/counters 0 and 1 by INT pin In addition to control by TR0 and TR1 bits of timer control register (TC[...]

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    INTERNAL SPECIFICATIONS 81 TIMER 0 or TIMER 1 CLOCK DETECTOR XTAL 1 ÷ 12 S3 Q D L S5 INT0 or INT1 ✽ GATE TR0 or TR1 T0 or T1 C/ T Figure 4-10 INT 0 and INT 1 timer/counter start/stop control circuit Table 4-10 GATE· INT ·TR timer/counter control tables GATE TR0 INT 0 RUN STOP TIMER 0 0 0 × • 0 1 × • 1 0 0 • 1 1 0 • 1 1 1 • GATE TR1[...]

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    MSM80C154S/83C154S/85C154HVS 82 4.5.2.5 Timer/counters 0/1 timer modes 4.5.2.5.1 Outline The timer/counter 0 and 1 timer modes are set by combinations of M0 and M1 bit data in the timer mode register (TMOD 89H) shown in Table 4-11. The timer modes which can be set are 0, 1, 2, and 3. Timer/counter 0 modes are specified by M0 and M1 of bits 0 and 1,[...]

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    INTERNAL SPECIFICATIONS 83 DETECTOR XTAL 1 ÷ 12 S3 GATE C/ T DATA INT 0 PIN (PORT 3.2) LATCH S5 Q TR0 T0 PIN (PORT 3.4) Q0------Q4 TL0 (5BITS) Q0------Q7 TH0 (8BITS) C DETECTOR TF0 Figure 4-11 Timer/counter 0 mode 0 DETECTOR XTAL 1 ÷ 12 S3 GATE C/ T DATA INT 1 PIN (PORT 3.3) LATCH S5 Q TR1 T1 PIN (PORT 3.5) Q0------Q4 TL1 (5BITS) Q0------Q7 TH1 ([...]

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    MSM80C154S/83C154S/85C154HVS 84 4.5.2.5.3 Mode 1 M1 M0 01 In mode 1, timer/counters 0 and 1 both become 16-bit timer/counters by the circuit connection shown in Figures 4-13 and 4-14. TL0 and TL1 in timer/counters 0 and 1 serve as the counter for the eight lower bits, and TH0 and TH1 serve as the counter for the eight upper bits. TL0 is set by the [...]

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    INTERNAL SPECIFICATIONS 85 DETECTOR XTAL 1 ÷ 12 S3 GATE C/ T DATA INT 0 PIN (PORT 3.2) LATCH S5 Q TR0 T0 PIN (PORT 3.4) Q0------Q7 TL0 (8BITS) Q0------Q7 TH0 (8BITS) C DETECTOR TF0 Figure 4-13 Timer/counter 0 model DETECTOR XTAL 1 ÷ 12 S3 GATE C/ T DATA INT 1 PIN (PORT 3.3) LATCH S5 Q TR1 T1 PIN (PORT 3.5) Q0------Q7 TL1 (8BITS) Q0------Q7 TH1 (8[...]

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    MSM80C154S/83C154S/85C154HVS 86 4.5.2.5.4 Mode 2 M1 M0 10 In mode 2, timer/counters 0 and 1 both become 8-bit timer/counters with 8-bit auto reloader registers by the circuit connection shown in Figures 4-15 and 4-16. TH0 and TH1 in timer/ counters 0 and 1 serve as the 8-bit auto reloader section, and TL0 and TL1 serve as the timer/ counter section[...]

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    INTERNAL SPECIFICATIONS 87 DETECTOR XTAL 1 ÷ 12 S3 GATE C/ T DATA INT 0 PIN (PORT 3.2) LATCH S5 Q TR0 T0 PIN (PORT 3.4) Q0------Q7 TL0 (8BITS) C DETECTOR TF0 Q0------Q7 TH0 (8BITS) RELOAD DATA Figure 4-15 Timer/counter 0 mode 2 DETECTOR XTAL 1 ÷ 12 S3 GATE C/ T DATA INT 1 PIN (PORT 3.3) LATCH S5 Q TR1 T1 PIN (PORT 3.5) Q0------Q7 TL1 (8BITS) C DE[...]

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    MSM80C154S/83C154S/85C154HVS 88 4.5.2.5.5 Mode 3 M1 M0 11 In mode 3, timer/counter 0 TL0 and TH0 become independent 8-bit timer/counters by the circuit connection shown in Figure 4-17. Timer/counter 1 does not operate when mode 3 is set. The TL0 8-bit timer/counter is controlled in the same way as the regular timer/counter 0, TF0 being set if a car[...]

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    INTERNAL SPECIFICATIONS 89 4.5.2.5.6 32-bit timer mode When “1” is set in bit 6 (T32) of the I/O control register (IOCON 0F8H), timer/counters 0 and 1 are connected serially as indicated in Figure 4-18 to become a 32-bit timer/counter. This 32-bit timer/counter is started by the following procedure. First, “0” is set in TR0, TR1, TF0, and T[...]

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    MSM80C154S/83C154S/85C154HVS 90 4.5.2.5.7 Caution about use of timer counters 0 and 1 Since the internal clock stops operation during soft power down mode (PD), the auto-reload operation is not executed if timer/counters 0 and 1 are set to mode 2 or mode 3. If the power down mode is to be cancelled by the timer, timer/counters 0 and 1 must be set t[...]

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    INTERNAL SPECIFICATIONS 91 4.5.2.5.8 Caution about use of timer counters 0 and 1 when setting software power down mode When setting sofware power down mode, if the value of a timer counter by which a timer interrupt is set is immediately before overflow, the software power down mode can not be set. (Example) Timer 0 is in mode 1 of external clock. [...]

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    MSM80C154S/83C154S/85C154HVS 92 4.5.3 Timer/counter 2 4.5.3.1 Outline Timer/counter 2 is equipped with 16-bit binary counting and Read/Write functions. This timer/ counter is controlled entirely by timer 2 control register (T2CON 0C8H). The operating modes are 16-bit auto reload mode, capture mode, and baud rate generator mode. Modes are specified [...]

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    INTERNAL SPECIFICATIONS 93 EXF2 : Timer/counter 2 external flag bit which is set when the T2EX pin level (bit 1 of port 1) is changed from “1” to “0” at EXEN2=1. This flag serves as the timer interrupt 2 request signal. When an interrupt is generated, this flag must be reset to “0” by software. TF2 : Timer/counter 2 internal flag bit wh[...]

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    MSM80C154S/83C154S/85C154HVS 94 XTAL 1 ÷ 12 S3 DETECTOR T2 [PORT 1.0] Q0------Q7 TL2 8 BIT C RCAP2L Q0------Q7 TH2 8 BIT C RCAP2H DETECTOR T2EX [PORT 1.1] TR2 EXEN2 DETECTOR DETECTOR TF2 EXF2 TIMER 2 INTERRUPT RCLK=0 TCLK=0 CP/ RL2 =0 C/ T2 Figure 4-20 Timer/counter 2 16-bit auto reload mode circuit 4.5.3.3.2 16-bit capture mode The 16-bit capture[...]

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    INTERNAL SPECIFICATIONS 95 XTAL 1 ÷ 12 S3 DETECTOR T2 [PORT 1.0] Q0------Q7 TL2 8 BIT C RCAP2L Q0------Q7 TH2 8 BIT C RCAP2H DETECTOR T2EX [PORT 1.1] TR2 EXEN2 DETECTOR DETECTOR TF2 EXF2 TIMER 2 INTERRUPT RCLK=0 TCLK=0 CP/ RL2 =1 C/ T2 Figure 4-21 Timer/counter 2 16-bit capture mode circuit 4.5.3.3.3 16-bit baud rate generator mode The 16-bit baud[...]

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    MSM80C154S/83C154S/85C154HVS 96 XTAL 1 ÷ 2 S3 DETECTOR T2 [PORT 1.0] Q0------Q7 TL2 8 BIT C RCAP2L Q0------Q7 TH2 8 BIT C RCAP2H DETECTOR T2EX [PORT 1.1] TR2 EXEN2 DETECTOR EXF2 TIMER 2 INTERRUPT *RCLK+TCLK=1 CP/ RL2 = × C/ T2 RCLK TCLK ÷ 2 TIMER 1 OVERFLOW SMOD[PCON bit 7] ÷ 16 RX CLOCK [MODE1, 3] ÷ 16 TX CLOCK [MODE1, 3] Figure 4-22 Timer/co[...]

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    INTERNAL SPECIFICATIONS 97 4.5.3.4 Timer/counter 2 detector circuit 4.5.3.4.1 T2 (timer/counter 2 external clock detector) The T2 detector circuit block diagram is shown in Figure 4-23. Operation of this circuit is outlined below. When the level of the signal applied to T2 (bit 0 of port 1) is changed from “1” to “0”, output of F/Fl becomes[...]

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    MSM80C154S/83C154S/85C154HVS 98 4.5.3.5 Timer/counter carry signal detector circuit The detector circuit shown in Figure 4-25 is inserted between the MSM80C154S/ MSM83C154S timer/counter carry output and the timer flag. The purpose of this detector is to prevent timer flags being set by the timer carry signal during execution of OR, AND, EOR, RESET[...]

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    INTERNAL SPECIFICATIONS 99 4.6 Serial Port 4.6.1 Outline MSM80C154S/MSM83C154S is equipped with a serial port which can be used in I/O extension and UART (Universal Asynchronous Receiver/Transmitter) applications. I/O extension mode • Input and output of 8-bit serial data synchronized with the MSM80C154S/MSM83C154S output clock. UART mode • Ind[...]

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    MSM80C154S/83C154S/85C154HVS 100 SCON SMOD TCLK RCLK SERR TX CONTROL RX CONTROL (PCON.7) (T2CON.4) (T2CON.5) (IOCON.5) SBUF (R) INPUT SHIFT REGISTER SBUF (T) MULTIPLEXER RXD (P3.0) MULTIPLEXER TXD (P3.1) SHIFT CLOCK INTERNAL BUS TIMER/COUNTER1 OVERFLOW TIMER/COUNTER2 OVERFLOW 1/2OSC. Note: : Internal bus connection : Serial data flow and shift cloc[...]

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    INTERNAL SPECIFICATIONS 101 4.6.2 Special function registers for serial port 4.6.2.1 SCON (Serial Port Control Register) SCON is an 8-bit special function register consisting of control bits for specifying serial port operation modes and enabling/disabling data reception, storage bits for the ninth data bit transmitted and received during 11-bit fr[...]

  • Pagina 109

    MSM80C154S/83C154S/85C154HVS 102 Table 4-15 SCON Bit Symbol Function 0 1 2 3 4 5 6 7 RI TI RB8 TB8 REN SM2 SM1 SM0 "End of reception" flag. This is the interrupt request flag set by hardware when reception of one frame has been completed. The interrupt is generated by ORing with the T1 flag. Since the flag cannot be cleared by hardware, i[...]

  • Pagina 110

    INTERNAL SPECIFICATIONS 103 Table 4-16 Serial port operation modes SM0 0 0 1 1 SM1 0 1 0 1 Mode 0 1 2 3 Function I/O extension 10-bit frame UART 11-bit frame UART 11-bit frame UART Baud rate 1/12 F OSC Vareable 1/32 F OSC or 1/64 F OSC Vareable Note: F OSC denotes frequency of fundamental oscillator (XTAL1·2). 4.6.2.2 SBUF (serial port buffer regi[...]

  • Pagina 111

    MSM80C154S/83C154S/85C154HVS 104 4.6.2.5 SMOD SMOD controls the division of the baud rate clock source when the serial port is in UART mode (mode 1, 2, or 3). If SMOD is cleared when in mode 1 or 3, the timer/counter 1 overflow frequency divided by 2 becomes the baud rate clock source. And if SMOD is set, the timer/counter 1 overflow becomes the ba[...]

  • Pagina 112

    INTERNAL SPECIFICATIONS 105 4.6.2.6 SERR SERR is the status flag set when a framing error or overrun error is generated during UART mode (mode 1, 2, or 3). Framing error: The SERR flag is set when no stop bit is detected in UART mode. Framing error is detected irrespective of the data reception conditions set by SM2. Overrun error: The SERR flag is[...]

  • Pagina 113

    MSM80C154S/83C154S/85C154HVS 106 4.6.3 Operating modes 4.6.3.1 Mode 0 4.6.3.1.1 Outline Mode 0 is the I/O extension mode where input and output of 8-bit data via RXD (P3.0) is synchronized with the output clock from TXD (P3.1). The baud rate in mode 0 is fixed to 1/12th of the fundamental oscillator (XTAL1·2) frequency to enable the serial port to[...]

  • Pagina 114

    INTERNAL SPECIFICATIONS 107 SBUF (R) INPUT SHIFT REG. INTERNAL BUS RI SBUF (T) START START INTERNAL BUS TI REN SHIFT CLOCK ENABLE TXD RXD WRITE TO SBUF SERIAL PORT INTERRUPT Figure 4-28 Serial port (mode 0)[...]

  • Pagina 115

    MSM80C154S/83C154S/85C154HVS 108 Figure 4-29 Serial port (mode 0) timing chart D1 WRITE TO SBUF RXD TXD ALE S4 S5 S6 S1 S2 S3 TERMINATE TRANSMISSION TI S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 D2 D3 D4 D5 D6 S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 WRITE TO SCON REN?[...]

  • Pagina 116

    INTERNAL SPECIFICATIONS 109 Figure 4-30 Serial port (mode 0) timing and corresponding basic MSM80C154S/ MSM83C154S timing XTAL1 ALE OUTPUT: READ RXD INPUT: TXD (SHIFT CLOCK) RXD (DATA OUTPUT) S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 TXD (SHIFT CLOCK)[...]

  • Pagina 117

    MSM80C154S/83C154S/85C154HVS 110 4.6.3.2 Mode 1 4.6.3.2.1 Outline Mode 1 is the 10-bit frame UART mode (with one start bit, eight data bits, and one stop bit) where the baud rate may be set to any value depending on the timer/counter 1 or timer/ counter 2 setting. A block diagram of the serial port in mode 1 is shown in Figure 4-31, and the operati[...]

  • Pagina 118

    INTERNAL SPECIFICATIONS 111 B = f OSC × 65536-D RCAP2 1 × 16 1 2 1 × where B is the baud rate, f OSC the fundamental frequency (XTAL1·2), and D RCAP2 the contents of RCAP2L and RCAP2H (expressed in decimal). 4.6.3.2.3 Mode 1 transmit operation The transmit basic clock (TXCLOCK in Figure 4-31) is obtained from the overflow of a hexadecimal free-[...]

  • Pagina 119

    MSM80C154S/83C154S/85C154HVS 112 4.6.3.2.5 Mode 1 UART error detection If the following two conditions are satisfied when the hexadecimal counter is in state 10 during reception of the stop bit, it is assumed that new data is received before processing of the previously received data has been completed. Hence, an overrun error is generated, and the[...]

  • Pagina 120

    INTERNAL SPECIFICATIONS 113 Figure 4-31 Serial port (mode 1) SBUF (R) INPUT SHIFT REG. INTERNAL BUS RI SBUF (T) START START INTERNAL BUS TI RXD SAMPLE LOGIC 1/16 COUTER TXD RXD WRITE TO SBUF SERIAL PORT INTERRUPT REN SM2 RECEIVE DATA NEGLECT LOGIC SERR BAUD RATE CLOCK RCLK RCLK=1 RCLK=0 1/16 COUTER BAUD RATE CLOCK TCLK TCLK=1 TCLK=0 TIMER/COUNTER2 [...]

  • Pagina 121

    MSM80C154S/83C154S/85C154HVS 114 Figure 4-32 Serial port (mode 1) timing chart D1 WRITE TO SBUF TXD TERMINATE TRANSMISSION TX CLOCK TI D2 D3 D4 D5 D6 RX COUNTER RUN RXD SAMPLE CLOCK LOAD SBUF RXD SHIFT-IN CLOCK RI or SERR SET TERMINATE RECEPTION STOP BIT STOP BIT M1·S3 D7 D0 D1 D2 D3 D4 D5 D6 D7 D0 M1·S3 START BIT START BIT[...]

  • Pagina 122

    INTERNAL SPECIFICATIONS 115 4.6.3.3 Mode 2 4.6.3.3.1 Outline Mode 2 is an 11-bit frame UART mode (with one start bit, eight data bits, one multipurpose data bit, and one stop bit) where the baud rate is 1/64th or 1/32nd of the fundamental oscillator (XTAL1·2) frequency. A block diagram of the serial port in mode 2 is shown in Figure 4-33, and the [...]

  • Pagina 123

    MSM80C154S/83C154S/85C154HVS 116 When this “1” to “0” RXD change is detected, the hexadecimal counter which had been stopped in reset status commences to count up. When the hexadecimal counter is in state 7, 8, and 9, the start bit is sampled, and is accepted as valid if at least two of the three sampled values are “0”, thereby enabling[...]

  • Pagina 124

    INTERNAL SPECIFICATIONS 117 SBUF (R) INPUT SHIFT REG. INTERNAL BUS RI START START SBUF (T) INTERNAL BUS TI RXD SAMPLE LOGIC 1/16 COUTER TXD RXD WRITE TO SBUF SERIAL PORT INTERRUPT REN SM2 RECEIVE DATA NEGLECT LOGIC SERR BAUD RATE CLOCK 1/16 COUTER BAUD RATE CLOCK SMOD SMOD=1 SMOD=0 1/2 TBB 1/2 XTAL1·2 Figure 4-33 Serial port (mode 2)[...]

  • Pagina 125

    MSM80C154S/83C154S/85C154HVS 118 D1 WRITE TO SBUF TXD TERMINATE TRANSMISSION TX CLOCK TI D2 D3 D4 D5 D6 RX COUNTER RUN RXD SAMPLE CLOCK LOAD SBUF RXD SHIFT-IN CLOCK RI or SERR SET TERMINATE RECEPTION STOP BIT STOP BIT M1·S3 TBB D0 D1 D2 D3 D4 D5 D6 RBB D0 M1·S3 START BIT START BIT D7 D7 Figure 4-34 Serial port (mode 2) timing chart[...]

  • Pagina 126

    INTERNAL SPECIFICATIONS 119 4.6.3.4 Mode 3 4.6.3.4.1 Outline Mode 3 is another 11-bit frame UART mode (with one start bit, eight data bits, one multi- purpose data bit, and one stop bit). Whereas the baud rate is 1/64th or 1/32nd of the fundamental oscillator frequency in mode 2, the mode 3 baud rate can be freely selected according to the timer/co[...]

  • Pagina 127

    MSM80C154S/83C154S/85C154HVS 120 B = f OSC × 65536-D RCAP2 1 × 16 1 2 1 × where B is the baud rate, f OSC the fundamental oscillator (XTAL1·2) frequency, and D RCAP2 the contents of R CAP2L and R CAP2H (expressed in decimal). 4.6.3.4.3 Mode 3 transmit operation The transmit basic clock (TXCLOCK in Figure 4-36) is obtained from a hexadecimal fre[...]

  • Pagina 128

    INTERNAL SPECIFICATIONS 121 If the above conditions are not satisfied when the hexadecimal counter is in state 10 during the multi-purpose data bit interval, the received data is disregarded, the SBUF, RB8, and RI flags remain unchanged, and the receive circuit is initialized when the hexadecimal counter is in state 10 during the stop bit interval.[...]

  • Pagina 129

    MSM80C154S/83C154S/85C154HVS 122 SBUF (R) INPUT SHIFT REG. INTERNAL BUS RI SBUF (T) START START INTERNAL BUS TI RXD SAMPLE LOGIC 1/16 COUTER TXD RXD WRITE TO SBUF SERIAL PORT INTERRUPT REN SM2 RECEIVE DATA NEGLECT LOGIC SERR BAUD RATE CLOCK RCLK RCLK=1 RCLK=0 1/16 COUTER BAUD RATE CLOCK TCLK TCLK=1 TCLK=0 TIMER/COUNTER2 OVERFLOW SMOD SMOD=1 SMOD=0 [...]

  • Pagina 130

    INTERNAL SPECIFICATIONS 123 D1 WRITE TO SBUF TXD TERMINATE TRANSMISSION TX CLOCK TI D2 D3 D4 D5 D6 RX COUNTER RUN RXD SAMPLE CLOCK LOAD SBUF RXD SHIFT-IN CLOCK RI or SERR SET TERMINATE RECEPTION STOP BIT STOP BIT M1·S3 TBB D0 D1 D2 D3 D4 D5 D6 RBB D0 M1·S3 START BIT START BIT D7 D7 Figure 4-36 Serial port (mode 3) timing chart[...]

  • Pagina 131

    MSM80C154S/83C154S/85C154HVS 124 4.6.4 Serial port application examples 4.6.4.1 I/O extension I/O extension can be achieved by using the serial port in mode 0. An input extension example is shown in Figure 4-37 and the corresponding timing chart is shown in Figure 4-38. Following output of the latch pulse from PX.X, REN=“1” and R1=“0” are s[...]

  • Pagina 132

    INTERNAL SPECIFICATIONS 125 An output extension example is shown in Figure 4-39 and the corresponding timing chart is shown in Figure 4-40. After output data has been written into SBUF and the output sequence completed, the latch pulse output from PX.X is obtained and the 74LS164 data is shifted to 74LS373. PX.X MSM80C154S MSM83C154S RXD TXD 8Q 7Q [...]

  • Pagina 133

    MSM80C154S/83C154S/85C154HVS 126 PX.X MSM80C154S MSM83C154S OUTPUT CONTROL PX.X INPUT CONTROL RXD TXD 8Q 7Q 6Q 5Q 4Q 3Q 2Q 1Q 8D 7D 6D 5D 4D 3D 2D 1D OC G 74LS373 QH QG QF QE QD QC QB QA CLK CK 74LS164 BA QH HG F E DC B A INHIBIT CK 74LS165 CLOCK SERIAL IN SHIFT/ LOAD INPUT OUTPUT V CC V CC 74LS126 Figure 4-41 Input/output extension example[...]

  • Pagina 134

    INTERNAL SPECIFICATIONS 127 RXD TXD OUTPUT CONTROL INPUT CONTROL INPUT OUTPUT 74LS165 OUTPUT MSM80C154S/MSM83C154S OUTPUT In all examples, additional multiple bit I/O extension is made possible by multiple cascade connections of 74LS164 or 74LS165. Figure 4-42 lnput/output extension example timing chart[...]

  • Pagina 135

    MSM80C154S/83C154S/85C154HVS 128 4.6.4.2 Multi-processor systems Multi-processor systems can be formed with MSM80C154S/MSM83C154S by using the serial port in mode 2 or mode 3 for inter-processor communications. If reception data bit 9 (multi-purpose data bit) is “1” when SM2 is set in mode 2 or 3, reception data is received and an interrupt is [...]

  • Pagina 136

    4.7 Interrupt 4.7.1 Outline MSM80C154S/MSM83C154S is equipped with six interrupts. 1. INT 0 External interrupt 0 2. TM0 Timer interrupt 0 3. INT 1 External interrupt 1 4. TM1 Timer interrupt 1 5. SI/O Serial port interrupt 6. TM2 Timer interrupt 2 These six interrupts are controlled by interrupt enable register (IE) and interrupt priority register [...]

  • Pagina 137

    MSM80C154S/83C154S/85C154HVS 130 Figure 4-44 Interrupt control equivalent circuit INTERRUPT REQUEST FLAG REGISTER INTERRUPT ENABLE REGISTER INTERRUPT PRIORITY REGISTER SOURCE ENABLE PX0 IP.0 PI NI EX0 IE.0 PT0 IP.1 PI NI EX0 IE.0 PX1 IP.2 PI NI EX0 IE.0 PT1 IP.3 PI NI EX0 IE.0 PS IP.4 PI NI EX0 IE.0 PT2 IP.5 PI NI EX0 IE.0 EA IE.7 V CC PCT IP.7 V C[...]

  • Pagina 138

    INTERNAL SPECIFICATIONS 131 4.7.2 Interrupt enable register (IE) The function of the interrupt enable register (IE, 0A8H) is to enable or disable interrupt processes when an interrupt is requested. To execute the intended interrupt routine, the interrupt is first enabled by setting “1” in the corresponding interrupt bit in the interrupt enable [...]

  • Pagina 139

    MSM80C154S/83C154S/85C154HVS 132 4.7.3 Interrupt priority register (IP) The function of the interrupt priority register (IP, 0B8H) is to allocate rights to commence interrupt routines on a priority basis when an interrupt is requested. Interrupt priority can be programmed by setting the bit corresponding to the interrupt request in the interrupt pr[...]

  • Pagina 140

    INTERNAL SPECIFICATIONS 133 4.7.3.1 Priority interrupt routine flow The flow of interrupt processing when a priority interrupt is generated and processed after a routine has been commenced by a non-priority interrupt generated during execution of a main routine program is outlined in Figure 4-45 below. This diagram shows the flow chart up to the po[...]

  • Pagina 141

    MSM80C154S/83C154S/85C154HVS 134 4.7.3.2 Interrupt routine flow when priority circuit is stopped When bit 7 (PCT) of the priority register (IP 0B8H) is set to “1”, all interrupt control is transferred to the interrupt enable register (IE 0A8H). When this mode is set, the interrupt disable instruction (CLR EA) must always be placed at the beginn[...]

  • Pagina 142

    INTERNAL SPECIFICATIONS 135 4.7.3.3 Interrupt priority when priority register (IP) contents are all “0” The interrupt priority when the priority register (IP, 0B8H) contents are all “0” indicates the priority in which a certain interrupt is processed in preference to other interrupts when interrupt requests are generated simultaneously. As [...]

  • Pagina 143

    MSM80C154S/83C154S/85C154HVS 136 4.7.4 Detection of external interrupt signals INT 0 and INT 1 4.7.4.1 Outline of INT signal detection Detect modes of the external interrupt signals 0 and 1 can be set to level-detect or trigger- detect mode by the IT0 and IT1 data values in the timer control register (TCON 88H) as indicated in Table 4-22. Table 4-2[...]

  • Pagina 144

    INTERNAL SPECIFICATIONS 137 4.7.4.3 External interrupt signal 0 and 1 trigger detection When bit 0 (IT0) in the timer Control register (TCON 88H) is “1”, external interrupt 0 is edge- activated. And when bit 2 (IT1) is “1”, external interrupt 1 is also edge-activated. With the external interrupt signals in trigger-detect mode, external inte[...]

  • Pagina 145

    MSM80C154S/83C154S/85C154HVS 138 4.7.5 MSM80C154S/MSM83C154S interrupt response time charts 4.7.5.1 Interrupt response time chart when interrupt conditions are satisfied during execution of ordinary instructions in main routine If interrupt conditions are satisfied during execution of an ordinary instruction (which does not manipulate IE or IP) in [...]

  • Pagina 146

    INTERNAL SPECIFICATIONS 139 S4 S5 S6 S1 S2 S3 XTAL1 ALE Timer flag 1 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 Instruction execution S6 1 - 0 1 0 - M1~M4 M1 or M2 M1~M4 M1 or M2 M1 M2 1 - 0 Execution of one instruction Execution of one instruction Timer 1 interrput address call Figure 4-49 lnterrupt response time chart when interrupt co[...]

  • Pagina 147

    MSM80C154S/83C154S/85C154HVS 140 4.7.5.2 Interrupt response time chart when interrupt conditions are satisfied during execution of IE or IP register operation instruction in main routine If interrupt conditions are satisfied during execution of an instruction used to manipulate the interrupt enable register (IE) or the interrupt priority register ([...]

  • Pagina 148

    INTERNAL SPECIFICATIONS 141 S4 S5 S6 S1 S2 S3 XTAL1 ALE Timer flag 1 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 Instruction execution S6 1 - 0 1 0 - M1 or M2 M1~M4 M1 or M2 M1 M2 1 - 0 Execution of IE or IP manipulation instruction Execution of one instruction Timer 1 interrput address call Figure 4-50 Interrupt response time chart when [...]

  • Pagina 149

    MSM80C154S/83C154S/85C154HVS 142 4.7.5.3 Interrupt response time chart when an ordinary instruction is executed after temporarily returning to the main routine from continuous interrupt processing If an ordinary instruction (which does not manipulate IE or IP) is executed after returning to the main routine following execution of the interrupt rout[...]

  • Pagina 150

    INTERNAL SPECIFICATIONS 143 Figure 4-51 Interrupt response time chart when ordinary instruction is executed after returning to main routine during continuous interrupt processing S4 S5 S6 S1 S2 S3 XTAL1 ALE Timer flag 1 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 Instruction execution S6 1 - 0 1 0 - M2 M1~M4 M1 or M2 M1 M2 1 0 RETI execut[...]

  • Pagina 151

    MSM80C154S/83C154S/85C154HVS 144 4.7.5.4 Interrupt response time chart when an IE or IP manipulating instruction is executed after temporarily returning to the main routine from continuous interrupt processing If the next interrupt conditions are satisfied during execution of an interrupt processing routine and the interrupt terminating instruction[...]

  • Pagina 152

    INTERNAL SPECIFICATIONS 145 Figure 4-52 Interrupt response time chart when IE or IP manipulating instruction is executed after returning to main routine during continuous interrupt processing S4 S5 S6 S1 S2 S3 XTAL1 ALE Timer flag 1 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 Instruction execution S6 1 - 0 1 0 - M2 M1 or M2 M1 1 0 RETI ex[...]

  • Pagina 153

    MSM80C154S/83C154S/85C154HVS 146 4.8 CPU “Power Down” 4.8.1 Outline Since the internal MSM80C154S/MSM83C154S circuits have been designed as completely static circuits, all internal information (register data) is preserved if XTAL1·2 oscillation is stopped. This feature is utilized to incorporate a fuller range of power down modes. In idle mode[...]

  • Pagina 154

    INTERNAL SPECIFICATIONS 147 XTAL 2 XTAL 1 TIMER, S-I/O & INTERRUPT CPU CONTROL CLOCK Bit Set SMOD HPD RPD — GF1 GF0 PD IDL 76543210 *• PCON, 87H CONTROL Figure 4-53 ldle mode equivalent circuit[...]

  • Pagina 155

    MSM80C154S/83C154S/85C154HVS 148 Table 4-23 CPU pin details in idle mode Name Internal ROM External ROM P1.0/T2 Port data output Port data output P1.1/T2EX Port data output Port data output P1.2 Port data output Port data output P1.3 Port data output Port data output P1.4 Port data output Port data output P1.5 Port data output Port data output P1.6[...]

  • Pagina 156

    INTERNAL SPECIFICATIONS 149 Figure 4-54 Idle mode setting time chart (internal ROM mode) S1 S2 S3 S4 S5 S6 M1 or M2 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 W-PCON 1 0 *PCON-bit 0 1 0 IDLE MODE S6 PORT DATA PORT DATA PORT DATA PORT DATA IDLE SET CYCLE[...]

  • Pagina 157

    MSM80C154S/83C154S/85C154HVS 150 Figure 4-55 Idle mode setting time chart (external ROM mode) S1 S2 S3 S4 S5 S6 M1 or M2 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 W-PCON 1 0 *PCON-bit 0 1 0 IDLE MODE S6 PORT DATA PORT DATA FLOATING IDLE SET CYCLE PCL PCL PCL[...]

  • Pagina 158

    INTERNAL SPECIFICATIONS 151 4.8.3 Soft power down mode (PD) setting Soft power down mode (PD) is set when “1” is set in bit 1 (PD) of the power control register (PCON 87H). The circuit connection involved in this setting is shown in Figure 4-56. Soft power down mode cancellation conditions can be set through manipulation of bit 5 (RPD) of the p[...]

  • Pagina 159

    MSM80C154S/83C154S/85C154HVS 152 XTAL 2 XTAL 1 CPU CLOCK Bit Set SMOD HPD RPD — GF1 GF0 PD IDL 76543210 *• CONTROL PCON 87H IOCON 0F8H I/O FLOATING Bit Set — T32 SERR IZC P3HZ P2HZ P1HZ ALF 76543210 • Figure 4-56 Soft power down mode equivalent circuit[...]

  • Pagina 160

    INTERNAL SPECIFICATIONS 153 Q S R IE0 or 1 Q D L INT 0 or INT 1 PD S3 RESET S6 M END PCON5(RPD) PDRESET S5 Figure 4-57 Power down cancellation circuit at INTERRUPT level input S4 S2 S3 Q S L R IE0 or 1 PCON5(RPD) PDRESET D Q D L S3 D L S5 Q PD INT 0 or INT 1 W TCON BUS RESET Figure 4-58 Power down cancellation circuit at INTERRUPT edge input[...]

  • Pagina 161

    MSM80C154S/83C154S/85C154HVS 154 S3 Q D L Q D R F/F1 F/F2 S5 T0 or T1 V CC RESET PD F/F1 F/F2 PCON5(RPD) Q S R TF0 or 1 PDRESET RESET TIMER0, 1 C Figure 4-59 TIMER0, 1 power down cancellation circuit[...]

  • Pagina 162

    INTERNAL SPECIFICATIONS 155 Table 4-24 CPU pin details (ALF=0) in soft power down mode (PD) Name Internal ROM External ROM P1.0/T2 Port data output Port data output P1.1/T2EX Port data output Port data output P1.2 Port data output Port data output P1.3 Port data output Port data output P1.4 Port data output Port data output P1.5 Port data output Po[...]

  • Pagina 163

    MSM80C154S/83C154S/85C154HVS 156 S1 S2 S3 S4 S5 S6 M1 or M2 M1 XTAL1 1 0 ALE 1 0 PSEN PORT 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 W-PCON 1 0 *PCON-bit 1 1 0 SOFT POWER DOWN MODE S6 PORT DATA PORT DATA PD SET CYCLE 1 0 1 0 IOCON-bit 0 PORT DATA PORT DATA *ALF=“0” S1 PORT DATA PORT DATA PORT DATA PORT DATA Figure 4-60 Soft power down mode setting tim[...]

  • Pagina 164

    INTERNAL SPECIFICATIONS 157 Figure 4-61 Soft power down mode setting time chart (external ROM mode) S1 S2 S3 S4 S5 S6 M1 or M2 M1 XTAL1 1 0 ALE 1 0 PSEN PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 W-PCON 1 0 *PCON-bit 1 1 0 SOFT POWER DOWN MODE S6 PORT DATA PORT DATA FLOATING PD SET CYCLE PCL PCL PCL PCH PCH 1 0 PCH PORT DATA 1 0 IOCON-bit 0 PORT D[...]

  • Pagina 165

    MSM80C154S/83C154S/85C154HVS 158 Table 4-25 CPU pin details (ALF=1) in soft power down mode (PD) Name Internal ROM External ROM P1.0/T2 P1.1/T2EX P1.2 P1.3 P1.4 P1.5 P1.6 P1.7 RESET P3.0/RXD P3.1/TXD P3.2/ INT 0 P3.3/ INT 1 P3.4/ T0 P3.5/ T1/HPDI P3.6/ WR P3.7/ RD XTAL 2 XTAL 1 V SS P2.0 P2.1 P2.2 P2.3 P2.4 P2.5 P2.6 P2.7 PSEN ALE EA P0.7 P0.6 P0.5[...]

  • Pagina 166

    INTERNAL SPECIFICATIONS 159 Figure 4-62 Soft power down mode setting and I/O floating time chart (internal ROM mode) S1 S2 S3 S4 S5 S6 M1 or M2 M1 XTAL1 1 0 ALE 1 0 PSEN *PORT 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 W-PCON 1 0 PCON-bit 1 1 0 SOFT POWER DOWN MODE S6 PORT DATA PORT DATA PD SET CYCLE 1 0 1 0 IOCON-bit 0 *ALF=“1” S1 PORT DATA PORT DATA [...]

  • Pagina 167

    MSM80C154S/83C154S/85C154HVS 160 Figure 4-63 Soft power down mode setting and I/O floating time chart (external ROM mode) S1 S2 S3 S4 S5 S6 M1 or M2 M1 XTAL1 1 0 ALE 1 0 PSEN PORT 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 W-PCON 1 0 *PCON-bit 1 1 0 SOFT POWER DOWN MODE S6 PORT DATA PORT DATA PD SET CYCLE 1 0 1 0 IOCON-bit 0 *ALF=“1” S1 FLOATING FLOATI[...]

  • Pagina 168

    INTERNAL SPECIFICATIONS 161 4.8.4 Hard power down mode (HPD) setting To set hard power down mode (HPD), “1” is set in bit 6 (HPD) of the power control register (PCON 87H) in advance to attain the circuit connections shown in Figure 4-61. Hard power down mode is set when the level of the power failure detect signal applied to the HPDI pin (bit 5[...]

  • Pagina 169

    MSM80C154S/83C154S/85C154HVS 162 Figure 4-64 Hard power down mode equivalent circuit XTAL 2 XTAL 1 CPU CLOCK Bit Set SMOD HPD RPD — GF1 GF0 PD IDL 76543210 •• CONTROL PCON 87H IOCON 0F8H I/O FLOATING Bit Set — T32 SERR IZC P3HZ P2HZ P1HZ ALF 76543210 • HPDI[...]

  • Pagina 170

    INTERNAL SPECIFICATIONS 163 Table 4-26 CPU pin details (ALF=0) in hard power down mode (HPD) Name Internal ROM External ROM P1.0/T2 Port data output Port data output P1.1/T2EX Port data output Port data output P1.2 Port data output Port data output P1.3 Port data output Port data output P1.4 Port data output Port data output P1.5 Port data output P[...]

  • Pagina 171

    MSM80C154S/83C154S/85C154HVS 164 Figure 4-65 Hard power down mode setting time chart (internal ROM mode) S1 S2 S3 S4 S5 S6 M1 or M2 M1 XTAL1 1 0 ALE 1 0 PSEN PORT 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 *HPDI [P3.5] 1 0 PCON-bit 6 1 0 HARD POWER DOWN MODE S6 PORT DATA PORT DATA HPD SET CYCLE 1 0 1 0 IOCON-bit 0 PORT DATA PORT DATA *ALF=“0” S1 PORT D[...]

  • Pagina 172

    INTERNAL SPECIFICATIONS 165 Figure 4-66 Hard power down mode setting time chart (external ROM mode) S1 S2 S3 S4 S5 S6 M1 or M2 M1 XTAL1 1 0 ALE 1 0 PSEN PORT 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 *HPDI [P3.5] 1 0 PCON-bit 6 1 0 HARD POWER DOWN MODE S6 PORT DATA PORT DATA HPD SET CYCLE 1 0 1 0 IOCON-bit 0 PORT DATA PORT DATA *ALF=“0” S1 1 0 FLOATIN[...]

  • Pagina 173

    MSM80C154S/83C154S/85C154HVS 166 Table 4-27 CPU pin details (ALF=1) in hard power down mode (HPD) Name Internal ROM External ROM P1.0/T2 P1.1/T2EX P1.2 P1.3 P1.4 P1.5 P1.6 P1.7 RESET P3.0/RXD P3.1/TXD P3.2/ INT 0 P3.3/ INT 1 P3.4/ T0 P3.5/ T1/HPDI P3.6/ WR P3.7/ RD XTAL 2 XTAL 1 V SS P2.0 P2.1 P2.2 P2.3 P2.4 P2.5 P2.6 P2.7 PSEN ALE EA P0.7 P0.6 P0.[...]

  • Pagina 174

    INTERNAL SPECIFICATIONS 167 Figure 4-67 Hard power down mode setting and I/O floating time chart (internal ROM mode) S1 S2 S3 S4 S5 S6 M1 or M2 M1 XTAL1 1 0 ALE 1 0 PSEN PORT 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 PCON-bit 6 1 0 HARD POWER DOWN MODE S6 PORT DATA PORT DATA HPD SET CYCLE 1 0 1 0 IOCON-bit 0 *ALF=“1” S1 PORT DATA PORT DATA FLOATING FL[...]

  • Pagina 175

    MSM80C154S/83C154S/85C154HVS 168 Figure 4-68 Hard power down mode setting andl/Of loating time chart (external ROM mode) S1 S2 S3 S4 S5 S6 M1 or M2 M1 XTAL1 1 0 ALE 1 0 PSEN PORT 0 PORT 1 PORT 2 PORT 3 PCON-bit 6 1 0 HARD POWER DOWN MODE S6 HPD SET CYCLE 1 0 1 0 IOCON-bit 0 *ALF=“1” S1 *HPDI [P3.5] 1 0 1 0 1 0 1 0 PORT DATA PORT DATA FLOATING F[...]

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    INTERNAL SPECIFICATIONS 169 4.9 CPU Power Down Mode (IDLE, PD, and HPD) Cancellation (CPU Activation) 4.9.1 Outline CPU power down mode (IDLE, PD, and HPD) can be cancelled (CPU activation) in the following two ways. The CPU is reset when a “1” reset signal is applied to the CPU RESET pin, and the program is executed from address 0. This method[...]

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    MSM80C154S/83C154S/85C154HVS 170 Figure 4-69 Restart from idle mode by reset (internal ROM mode) S1 S2 S3 S4 S5 S6 M1 → M2 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 PCON-bit 0 1 0 *RESET 1 0 EXECUTE CYCLE RESET CYCLE M1 → M2 CPU RESET CONTROL 1 0 PORT DATA=[...]

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    INTERNAL SPECIFICATIONS 171 Figure 4-70 Restart from idle mode by reset (external ROM mode) S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE S6 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 PCON-bit 0 1 0 *RESET 1 0 EXECUTE CYCLE RESET CYCLE CPU RESET CONTROL 1 0 IDLE MODE PORT DATA=1 PORT DA[...]

  • Pagina 179

    MSM80C154S/83C154S/85C154HVS 172 Figure 4-71 Restart from soft power mode by reset (internal ROM mode) S1 S2 S3 S4 S5 S6 M1 → M2 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 PCON-bit 1 1 0 *RESET 1 0 EXECUTE CYCLE RESET CYCLE M1 → M2 CPU RESET CONTROL 1 0 PORT[...]

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    INTERNAL SPECIFICATIONS 173 Figure 4-72 Restart from soft power mode by reset (external ROM mode) S1 S2 S3 S4 S5 S6 M1 → M2 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 PCON-bit 1 1 0 *RESET 1 0 EXECUTE CYCLE RESET CYCLE M1 → M2 CPU RESET CONTROL 1 0 PORT DATA[...]

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    MSM80C154S/83C154S/85C154HVS 174 Figure 4-73 Restart from hard power down mode by reset (internal ROM mode) S1 S2 S3 S4 S5 S6 M1 → M2 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 IOCON-bit 0 1 0 *RESET 1 0 EXECUTE CYCLE RESET CYCLE M1 → M2 CPU RESET CONTROL 1 [...]

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    INTERNAL SPECIFICATIONS 175 Figure 4-74 Restart from hard power down mode by reset (external ROM mode) S1 S2 S3 S4 S5 S6 M1 → M2 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 IOCON-bit 0 1 0 *RESET 1 0 EXECUTE CYCLE RESET CYCLE M1 → M2 CPU RESET CONTROL 1 0 POR[...]

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    MSM80C154S/83C154S/85C154HVS 176 4.9.3 Cancellation of CPU power down mode (IDLE, PD) by interrupt signal When idle mode (IDLE) and soft power down mode (PD) are cancelled by interrupt signal, power down mode cancellation condition is determined by bit 5 (RPD) of the power control register (PCON 87H) shown in Table 4-29. When RPD is “0”, power [...]

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    INTERNAL SPECIFICATIONS 177 Figure 4-75 Equivalent circuit for, DLE and PD mode rancellation by interrupt signal IE0 [TCON.1] IE.0 TF0 [TCON.5] IE.1 IE1 [TCON.3] IE.2 TF1 [TCON.7] IE.3 RI/TI [SCON.0, 1] IE.4 EXF2/TF2[T2CON.6, 7] IE.5 IE.7 IDLE, PD MODE INTERRUPT & RESTART[...]

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    MSM80C154S/83C154S/85C154HVS 178 Figure 4-76 Restart from idle mode by interrupt INT 0 or 1 (internal ROM mode) S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 XTAL1 1 0 ALE S6 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 PCON-bit 0 1 0 * INT 0 or INT 1 1 0 INTERRUPT EXECUTE CYCLE WASTE CYCLE IE0 or IE1 [...]

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    INTERNAL SPECIFICATIONS 179 Figure 4-77 Restart from idle mode by interrupt INT 0 or 1 (external ROM mode) S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 XTAL1 1 0 ALE S6 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 PCON-bit 0 1 0 * INT 0 or INT 1 1 0 INTERRUPT EXECUTE CYCLE WASTE CYCLE IE0 or IE1 OUT 1[...]

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    MSM80C154S/83C154S/85C154HVS 180 Figure 4-78 Restart from soft power down mode by Interrupt INT 0 or 1 (internal ROM mode) S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M2 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 1 0 1 0 EXECUTE CYCLE WASTE CYCLE 1 0 PORT DATA PORT DATA PORT DATA SOFT POWER[...]

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    INTERNAL SPECIFICATIONS 181 Figure 4-79 Restart from soft power down mode by interrupt INT 0 or 1 (external ROM mode) S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M2 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 1 0 1 0 EXECUTE CYCLE WASTE CYCLE 1 0 PORT DATA PORT DATA SOFT POWER DOWN MODE M1 M[...]

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    MSM80C154S/83C154S/85C154HVS 182 4.9.3.2 Cancellation of CPU power down mode (IDLE, PD) by interrupt request signal and restart from next address of stop address To cancel idle mode (IDLE) or soft power down mode (PD) by interrupt request signal and then resume execution from the next address after the stop address, “1” is set in bit 5 (RPD) of[...]

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    INTERNAL SPECIFICATIONS 183 Figure 4-81 Restart from idle mode by INT 0 or 1 (internal ROM mode) S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 XTAL1 1 0 ALE S6 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 PCON-bit 0 1 0 * INT 0 or INT 1 1 0 INTERRUPT EXECUTE CYCLE WASTE CYCLE IE0 or IE1 OUT 1 0 IDLE MO[...]

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    MSM80C154S/83C154S/85C154HVS 184 Figure 4-82 Restart from idle mode by INT 0 or 1 (external ROM mode) S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M2 XTAL1 1 0 ALE S6 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 PCON-bit 0 1 0 INT 0 or INT 1 1 0 INTERRUPT EXECUTE CYCLE WASTE CYCLE *IE0 or IE1 OUT 1 0 IDL[...]

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    INTERNAL SPECIFICATIONS 185 Figure 4-83 Restart from soft power down mode by INT 0 or 1 (internal ROM mode) S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 1 0 1 0 EXECUTE CYCLE WASTE CYCLE 1 0 PORT DATA PORT DATA PORT DATA SOFT POWER DOWN MODE PORT DATA M1 PCON-bit [...]

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    MSM80C154S/83C154S/85C154HVS 186 Figure 4-84 Restart from soft power down mode by INT 0 or 1 (external ROM mode) S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 S2 S3 S4 S5 S6 M1 XTAL1 1 0 ALE 1 0 PSEN 1 0 PORT 0 1 0 PORT 1 1 0 PORT 2 1 0 PORT 3 1 0 1 0 1 0 EXECUTE CYCLE WASTE CYCLE 1 0 PORT DATA PORT DATA SOFT POWER DOWN MODE M1 PCON-bit 1 * INT 0 or IN[...]

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    INTERNAL SPECIFICATIONS 187 4.10 MSM80C154S/83C154S Battery Backup with Hard Power Down Mode Figures 4-85-1/2 and 2/2 show the examples of the MSM80C154S/83C154S battery backup circuits with hard power down mode. The hard power down mode serves to retain data stored in the CPU and external RAM if the AC 100V power failure occurs. Figure 4-85-1/2 sh[...]

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    MSM80C154S/83C154S/85C154HVS 188 Figure 4-85-1/2 MSM80C154S/83C154S battery back up with hard power down mode RD WR P0.0 P0.1 P0.2 P0.3 P0.4 P0.5 P0.6 P0.7 ALE P2.0 P2.1 P2.2 P2.3 P2.4 P2.5 P2.6 P2.7 EA PSEN P1 P3 XTAL1 XTAL2 V CC V SS RESET T1(P3.5) 10PF 1000 µ F 0.1 µ F 74HC08 74HC02 MSM80C154S/83C154S P0.0 P0.1 P0.2 P0.3 P0.4 P0.5 P0.6 P0.7 AL[...]

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    INTERNAL SPECIFICATIONS 189 Figure 4-85-2/2 MSM80C154S/83C154S battery back up with hard power down mode VCB P0.7 P0.6 P0.5 P0.4 P0.3 P0.2 P0.1 P0.0 CS7 CS0 P2.0 P2.1 P2.2 P0.7 P0.6 P0.5 P0.4 P0.3 P0.2 P0.1 P0.0 ALE OE WR VCA D7 D6 D5 D4 D3 D2 D1 D0 L Q7 Q6 Q5 Q4 Q3 Q2 Q1 Q0 GND V CC SN74LS373 D0 D1 D2 D3 D4 D5 D6 D7 A0 A1 A2 A3 A4 A5 A6 A7 A8 A9 A[...]

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    MSM80C154S/83C154S/85C154HVS 190 5. INPUT/OUTPUT POR TS[...]

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    INPUT/OUTPUT PORTS 191[...]

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    MSM80C154S/83C154S/85C154HVS 192 5. INPUT/OUTPUT PORTS 5.1 Outline MSM80C154S/MSM83C154S is equipped with four 8-bit input/output ports. The functions of these four ports (port 0, 1, 2, and 3) are listed below. 1) Port 0: Input/output bus port, address output port, and data input/output port. 2) Port 1: Quasi-bidirectional input/output port and con[...]

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    INPUT/OUTPUT PORTS 193 Q D MODIFY READ INTERNAL BUS N PORT 0 WPO Figure 5-2 Port 0 input/Output port equivalent circuit in internal ROM mode PC0~7 RA0~7 ACC0~7 READ INTERNAL BUS N P V CC PORT 0 Figure 5-3 Port 0 equivalent circuit during address and data input/output in external ROM/RAM mode[...]

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    MSM80C154S/83C154S/85C154HVS 194 PORT0 Accumulator bit Address 1 P0.0 ACC.0 PC RA –0 2 P0.1 ACC.1 PC RA –1 3 P0.2 ACC.2 PC RA –2 4 P0.3 ACC.3 PC RA –3 5 P0.4 ACC.4 PC RA –4 6 P0.5 ACC.5 PC RA –5 7 P0.6 ACC.6 PC RA –6 8 P0.7 ACC.7 PC RA –7 Table 5-1 Port 0 pin table[...]

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    INPUT/OUTPUT PORTS 195 5.3 Port 1 Port 1 is a quasi-bidirectional port capable of handling input and output of 8-bit data in the circuit configuration outlined in Figure 5-4. A “quasi-bidirectional port” refers to a port which has internal pull-up resistance when used as an input port. The internal equivalent circuit is shown in Figure 5-5. If [...]

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    MSM80C154S/83C154S/85C154HVS 196 Q D READ INTERNAL BUS WP1 MODIFY Q D C CONTROL P1 V CC P2 P3 PORT 1 N Figure 5-4 Port 1 internal equivalent circuit[...]

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    INPUT/OUTPUT PORTS 197 READ N OFF P3 ON R=100k Ω . . P2 ON R=10k Ω . . P1 ON R=500 Ω . . V CC INTERNAL BUS I OH (A) When accelerator circuit is activated READ N OFF P3 ON R=100k Ω . . P2 ON R=10k Ω . . P1 OFF R=500 Ω . . V CC INTERNAL BUS I OH (B) When "1" data is held OFF READ N ON P3 R=100k Ω . . P2 R=10k Ω . . P1 R=500 [...]

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    MSM80C154S/83C154S/85C154HVS 198 Figure 5-6 Quasi-bidirectional port accelerator circuit operation time chart S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 XTAL1 1- 0- ALE 1- 0- W-PORT 1- 0 PORT-OUT 1- 0 *P1·2·3TR-ON 1- 0 CPU-BUS 1 0 S2 S6 PSEN 1 0 PORT DATA="0" PORT DATA="1" * M1[...]

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    INPUT/OUTPUT PORTS 199 READ N OFF P2 ON R=10k Ω . . V CC INTERNAL BUS (A) "1" data writing equivalent circuit P3 ON R=100k Ω . . READ N OFF P2 ON R=10k Ω . . V CC INTERNAL BUS (B) "1" data input equivalent circuit P3 ON R=100k Ω . . I IH OFF ON 10k Ω V CC READ N OFF P2 OFF R=10k Ω . . V CC INTERNAL BUS (C) "0&qu[...]

  • Pagina 207

    MSM80C154S/83C154S/85C154HVS 200 PORT1 Function P1.0 T2 [TIMER COUNTER 2 EXTERNAL CLOCK] P1.1 T2EX [TIMER COUNTER 2 EXTERNAL CONTROL] Table 5-2 Port 1 CPU control pin table Table 5-3 Port 1 pin table PORT1 Accumulator bit 1 P1.0 ACC.0 2 P1.1 ACC.1 3 P1.2 ACC.2 4 P1.3 ACC.3 5 P1.4 ACC.4 6 P1.5 ACC.5 7 P1.6 ACC.6 8 P1.7 ACC.7[...]

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    INPUT/OUTPUT PORTS 201 5.4 Port 2 Port 2 can function as a quasi-bidirectional port capable of handling input and output of 8-bit data in the circuit configuration outlined in Figure 5-8. It can also be used for output of addresses 8 thru 15 in external ROM and external RAM (using DPTR) modes. When port 2 is used as a quasi-bidirectional port, it f[...]

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    MSM80C154S/83C154S/85C154HVS 202 PC/DATA P1 V CC P2 P3 PORT 2 N PC8~15 RA8~15 (DPH) Figure 5-9 Port 2 address output equivalent circuit for external memory Table 5-4 Port 2 pin table PORT2 Accumulator bit Address 1 P2.0 ACC.0 PC RA –8 2 P2.1 ACC.1 PC RA –9 3 P2.2 ACC.2 PC RA –10 4 P2.3 ACC.3 PC RA –11 5 P2.4 ACC.4 PC RA –12 6 P2.5 ACC.5 P[...]

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    INPUT/OUTPUT PORTS 203 5.5 Port 3 Port 3 can function as a quasi-bidirectional port capable of handling input and output of 8-bit data in the circuit configuration outlined in Figure 5-10, and can also be used as a CPU control pin. When port 3 is used as a quasi-bidirectional port, all functions are identical to those described for port 1. And when[...]

  • Pagina 211

    MSM80C154S/83C154S/85C154HVS 204 Table 5-5 Port 3 CPU control pin function table PORT3 PORT 3 PIN ALTERNATE FUNCTION P3.0 RXD [SERIAL INPUT PORT] P3.1 TXD [SERIAL OUTPUT PORT] P3.2 INT 0 [EXTERNAL INTERRUPT 0] P3.3 INT 1 [EXTERNAL INTERRUPT 1] P3.4 T0 [TIMER/COUNTER 0 CLOCK] P3.5 T1 [TIMER/COUNTER 1 CLOCK] P3.6 WR [EXTERNAL DATA MEMORY WRITE STROBE[...]

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    INPUT/OUTPUT PORTS 205 5.6 Port 0, 1, 2, and 3 Output and Floating Status Settings in CPU Power Down Mode (PD, HPD) The port 0, 1, 2, and 3 output status can be set to either data output or floating when MSM80C154S/MSM83C154S is in power down mode (PD, HPD). To set these ports to output status in power down mode, bit 0 (ALF) of the I/O control regi[...]

  • Pagina 213

    MSM80C154S/83C154S/85C154HVS 206 Bit Set — T32 SERR IZC P3HZ P2HZ P1HZ ALF 76543210 ••••• [IOCON 0F8H] Q D READ INTERNAL BUS W PORT MODIFY P2-10k Ω V CC P3-100k Ω I/O N PORT1, 2, 3 POWER DOWN Flag Figure 5-11 Control circuit for ports 0, 1, 2, 3 by lOCON[...]

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    INPUT/OUTPUT PORTS 207 5.7 High Impedance Input Port Setting of Each Ouasi-bidirectional Port 1, 2, and 3 Each of the quasi-bidirectional input ports 1, 2, and 3 can be set as high impedance input ports. This high impedance condition is achieved by setting “1” in bits 1 (P1HZ), 2 (P2HZ), and 3 (P3HZ) of the I/O control register (IOCON 0F8H) sho[...]

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    MSM80C154S/83C154S/85C154HVS 208 5.9 Precautions When Driving External Transistors by Ouasi-bidirectional Port Output Signals The following points must be carefully considered when quasi-bidirectional ports are used to drive a transistor by the circuit shown in Figure 5-12. Even though the CPU output in this circuit is at “1” level, the port ou[...]

  • Pagina 216

    INPUT/OUTPUT PORTS 209 V CC 10k Ω I B V CC P 100k Ω OUT CPU "1" OUT Figure 5-13 Drive circuit for NPN transistor by level shifter I B V CC OUT CPU "0" OUT Figure 5-14 PNP transistor direct connection drive circuit[...]

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    MSM80C154S/83C154S/85C154HVS 210 5.10 Port Output Timing 1) One machine cycle instruction output timing S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 XTAL1 1 0 ALE 1 0 W-PORT 1 0 PORT-OUT 1 0 PORT NEW DATA M1 PORT OLD DATA 1M CYCLE OP INC data address DEC data address MOV data address, A ORL data address, A ANL data address, A XRL data address, A XCH A[...]

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    INPUT/OUTPUT PORTS 211 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 S5 S6 M1 S1 XTAL1 1 0 ALE 1 0 W-PORT 1 0 PORT-OUT 1 0 PORT NEW DATA M2 PORT OLD DATA 2M CYCLE OP MOV data address, # data ORL data address, # data ANL data address, # data XRL data address, # data JBC bit address, code address POP data address MOV data address, @Rr MOV data address, Rr MOV data a[...]

  • Pagina 219

    MSM80C154S/83C154S/85C154HVS 212 5.11 Port Data Manipulating Instructions The MSM80C154S/MSM83C154S port operation instructions for ports 0, 1, 2, and 3 are divided into two groups-one where external signals applied to the port pin are used according to the instruction to be used, and the other where port latch data uneffected by the external signa[...]

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    INPUT/OUTPUT PORTS 213[...]

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    MSM80C154/83C154/85C154 214 6. ELECTRICAL CHARACTERISTICS[...]

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    ELECTRICAL CHARACTERISTICS 215[...]

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    MSM80C154/83C154/85C154 216 6. ELECTRICAL CHARACTERISTICS 6.1 Absolute Maximum Ratings Parameter Supply voltage Input voltage Storage temperature Symbol V CC V I T stg Ta=25°C Ta=25°C — Conditions –0.5~7 –0.5~V CC +0.5 –55~+150 Rating V V °C Unit 6.2 Operational Ranges Parameter Supply voltage Memory hold Ambient temperature Symbol V CC [...]

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    ELECTRICAL CHARACTERISTICS 217 6.3 DC Characteristics 1 (V CC =4.0 to 6.0V,V SS =0V, Ta=–40 ° C to +85 ° C) Parameter Input Low Voltage Input High Voltage Input High Voltage Output Low Voltage [PORT 1, 2,3] Output Low Voltage [PORT 0, ALE, PSEN ] Output High Voltage [PORT 1, 2,3] Output High Voltage [PORT 0, ALE, PSEN ] Logical 0 Input Current/[...]

  • Pagina 225

    MSM80C154/83C154/85C154 218 V CC Freq. 1MHz 3MHz 12MHz 16MHz 4V 2.2 3.7 12.0 16.0 5V 3.1 5.2 16.0 20.0 6V 4.1 7.0 20.0 25.0 Maximum Power Supply Current Normal Operation I CC (mA) V CC Freq. 24MHz 4.5V 25.0 5V 29.0 6V 35.0 V CC Freq. 1MHz 3MHz 12MHz 16MHz 4V 0.8 1.2 3.1 3.8 5V 1.2 1.7 4.4 5.5 6V 1.6 2.3 5.9 7.3 Maximum Power Supply Current Idle Mod[...]

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    ELECTRICAL CHARACTERISTICS 219 DC Characteristics 2 — Output High Voltage V OH1 I OH =–20 m A 0.75 V CC —V (PORT 0, ALE, PSEN ) –40 Logical 0 Input Current/ Logical 1 Output Current/ (PORT 1, 2, 3) I IL / I OH V I =0.1 V –5 — m A V O =0.1 V –300 Logical 1 to 0 Transition I TL V I =1.9 V — — m A Output Current (PORT 1, 2, 3) 125 RE[...]

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    MSM80C154/83C154/85C154 220 V CC V SS INPUT OUTPUT Note 3 V AI O Note 2 V IH V IL 12 34 V CC V SS INPUT OUTPUT Note 3 V A Note 2 V IH V IL V CC V SS INPUT OUTPUT V Note 1 V CC V SS INPUT OUTPUT Note 3 V IH V IL A A Note 1 : Repeated for specified input pins. 2 : Repeated for specified output pins. 3 : Input logic for specified status. Measuring cir[...]

  • Pagina 228

    ELECTRICAL CHARACTERISTICS 221 6.4 External Program Memory Access AC Characteristics V CC =2.2 to 6.0V, V SS =0V, Ta=–40 ° C to +85 ° C PORT 0, ALE, and PSEN connected with 100pF load, other connected with 80pF load Parameter Symble Unit Min. Max. 1 to 24 MHz Variable clock from 41.7 1000 ns t CLCL XTAL1, XTAL 2 Oscillation Cycle 2t CLCL -40 ?[...]

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    MSM80C154/83C154/85C154 222 External program memory read cycle tLHLL tA VLL tLLPL tPLPH tLLIV tPLIV tLLAX tAZPL tPXIX tPXIZ tPXA V tA VIV A0~A7 INSTR IN A0~A7 PO RT 0 A8~A15 A0~A7 PORT 2 A8~A15 ALE PSEN[...]

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    ELECTRICAL CHARACTERISTICS 223 6.5 External Data Memory Access AC Characteristics VCC=2.2 to 6.0V, VSS=0V, Ta=–40 ° C to +85 ° C PORT 0, ALE, and PSEN connected with 100pF load, other connected with 80pF load Parameter Symbol Unit Min. Max. 1 to 24 MHz Variable clock from 45.5 1000 ns t CLCL XTAL1, XTAL2 Oscillator Cycle 2t CLCL -40 — ns t LH[...]

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    MSM80C154/83C154/85C154 224 External data memory read cycle External data memory write cycle tLHLL tLLDV tLL WL tRLRH tA VLL tRHDX tRHDZ tA VDV A0~A7 RrorDPL DA T A IN PO RT 0 P2.0~P2.7 DA T A or A8~A15 PCH A8~A15 PCH PO RT 2 ALE PSEN A8~A15 PCH PCH A0~A7 PCL INSTR IN A0~A7 PCL tLLAX tA VWL tAZRL tRLDV RD tWHLH tLHLL tLL WL tWL WH tA VLL tWHQX A0~A[...]

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    ELECTRICAL CHARACTERISTICS 225 6.6 Serial Port (I/O Extension Mode) AC Characteristics V CC =2.2 to.0V, V SS =0V, Ta=–40 ° C to 85 ° C Parameter Serial Port Clock Cycle T ime Output Data Setup to Clock Rising Edge Output Data Hold After Clock Rising Edge Input Data Hold After Clock Rising Edge Clock Rising Edge to Input Data V alid Symbol tXLXL[...]

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    MSM80C154/83C154/85C154 226 VALID ALE SHIFT CLOCK INPUT DATA MACHINE CYCLE OUTPUT DATA tXLXL tQVXH tXHQX tXHDV tXHDX VALID VALID VALID VALID VALID VALID VALID[...]

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    ELECTRICAL CHARACTERISTICS 227 6.7 AC Characteristics Measuring Conditions 1. Input/output signal V IH V IL V IH V IL V OH V OL TEST POINT V OH V OL * The input signals in AC test mode are either V OH (logic “1”) orV OL (logic “0”). Timing measurements are made atV IH (logic “1”) and V IL (10gic “0”). 2. Floating V IH V IL V IH V IL[...]

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    MSM80C154/83C154/85C154 228 6.8 XTAL1 External Clock Input Waveform Conditions P arameter Oscillator F req. High Time Low Time Rise Time F all Time Symbol 1/tCLCL tCHCX tCLCX tCLCH tCHCL Min 0 15 15 — — Max 24 — — 5 5 Unit MHz ns ns ns ns tCHCX tCHCL tCHCX tCLCH tCLCL 0.7V CC 0.2V CC –0.1 V CC –0.5 0.45V EXTERMINAL OSCILLA TOR SIGNAL EX[...]

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    7. DESCRIPTION OF INSTR UCTIONS[...]

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    MSM80C154S/83C154S/85C154HVS 230[...]

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    DESCRIPTION OF INSTRUCTIONS 231 7. DESCRIPTION OF INSTRUCTIONS 7.1 Outline MSM80C154S/MSM83C154S is a microcontroller designed for parallel processing in an 8-bit ALU. The instructions consist of 8-bit units of data, and are available as 1-word 1 - machine, 2-machine, and 4-machine cycle instructions as well as 2-word 1-machine and 2-machine cycle [...]

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    MSM80C154S/83C154S/85C154HVS 232 7.2 Description of Instruction Symbols The instruction symbols have the following meanings. A Accumulator AB Register pair AC Auxiliary carry B Arithmetic operation register C Carry (the bit 7 carry represented by CY is changed to C in Chapter 7.) DPTR Data pointer PC Program counter Rr Register representation (r=0/[...]

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    DESCRIPTION OF INSTRUCTIONS 233 7.3 List of Instructions MSM80C154S/MSM83C154S instruction table 0 0000 1 0001 2 0010 3 0011 4 0100 5 0101 6 0110 7 0111 8 1000 9 1001 A 1010 B 1011 C 1100 D 1101 E 1110 F 1111 NOP AJMP address 11 (Page 0) LJMP address 16 RR A INC A INC direct INC @R0 INC @R1 INC R0 INC R1 INC R2 INC R3 INC R4 INC R5 INC R6 INC R7 JB[...]

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    MSM80C154S/83C154S/85C154HVS 234 7.4 Simplified Description of Instructions Note that “data address” is represented as “direct address” in this description. Mnemonic Instruction code D7 D6 D5 D4 D3 D2 D1 D0 Byte Cycle Description Page Classifi- cation Arithmetic operation instructions ADD ADD ADD ADD ADDC ADDC ADDC ADDC SUBB SUBB SUBB SUBB [...]

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    DESCRIPTION OF INSTRUCTIONS 235 Mnemonic Instruction code D7 D6 D5 D4 D3 D2 D1 D0 Byte Cycle Description Page Classifi- cation Accumulator operation instructions CLR CPL RL RLC RR RRC SWAP A A A A A A A 1 1 1 1 1 1 1 1 1 1 1 1 1 1 (A) ← 0 (A) ← ( A ) (A4~7) → ← (A0~3) 272 275 349 350 351 352 361 11100100 11110100 00100011 00110011 00000011 [...]

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    MSM80C154S/83C154S/85C154HVS 236 Mnemonic Instruction code D7 D6 D5 D4 D3 D2 D1 D0 Byte Cycle Description Page Classifi- cation Increment & decrement instructions Logical operation instructions INC INC INC INC INC DEC DEC DEC DEC ANL ANL ANL ANL ANL ANL ORL ORL ORL A Rr direct @Rr DPTR A Rr direct @Rr A, Rr A, direct A, @Rr A, #data direct, A d[...]

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    DESCRIPTION OF INSTRUCTIONS 237 Mnemonic Instruction code D7 D6 D5 D4 D3 D2 D1 D0 Byte Cycle Description Page Classifi- cation Immediate data setting instructions Logical operation instructions ORL ORL ORL XRL XRL XRL XRL XRL XRL MOV MOV MOV A, #data direct, A direct,#data A, Rr A, direct A, @Rr A, #data direct, A direct,#data A, #data Rr, #data di[...]

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    MSM80C154S/83C154S/85C154HVS 238 Mnemonic Instruction code D7 D6 D5 D4 D3 D2 D1 D0 Byte Cycle Description Page Classifi- cation Bit transfer instructions Carry flag operation instructions Immediate data setting instructions MOV MOV CLR SETB CPL ANL ANL ORL ORL MOV MOV SETB @Rr, #data DPTR, #data C C C C, bit C,/bit C, bit C,/bit C, bit bit, C bit 2[...]

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    DESCRIPTION OF INSTRUCTIONS 239 Mnemonic Instruction code D7 D6 D5 D4 D3 D2 D1 D0 Byte Cycle Description Page Classifi- cation Data transfer instructions Bit manipu- lation instructions Constant value instructions CPL MOV MOV MOV MOV MOV MOV MOV MOV MOV MOV MOV MOVC MOVC bit A, Rr A, direct A, @Rr Rr, A Rr, direct direct, A direct, Rr direct1, dire[...]

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    MSM80C154S/83C154S/85C154HVS 240 Mnemonic Instruction code D7 D6 D5 D4 D3 D2 D1 D0 Byte Cycle Description Page Classifi- cation Subroutine instructions Data exchange instructions XCH XCH XCH XCHD PUSH POP ACALL LCALL RET A, Rr A, direct A, @Rr A, @Rr direct direct addr 11 addr 16 1 2 1 1 2 2 2 3 1 1 1 1 1 2 2 2 2 2 (A) ← → (Rr) r=0~7 (A) ← ?[...]

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    DESCRIPTION OF INSTRUCTIONS 241 Mnemonic Instruction code D7 D6 D5 D4 D3 D2 D1 D0 Byte Cycle Description Page Classifi- cation Subroutine instructions Jump instructions Branching instructions RETI AJMP LJMP SJMP JMP CJNE addr 11 addr 16 rel @A+DPTR A, direct, rel 1 2 3 2 1 3 2 2 2 2 2 2 (PC 8~15 ) ← ((SP)) (SP) ← (SP)–1 (PC 0~7 ) ← ((SP)) ([...]

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    MSM80C154S/83C154S/85C154HVS 242 Mnemonic Instruction code D7 D6 D5 D4 D3 D2 D1 D0 Byte Cycle Description Page Classifi- cation Branching instructions CJNE CJNE A, #data, rel Rr,#data,rel 3 3 2 2 (PC) ← (PC)+3 IF (A) ≠ #data THEN (PC) ← (PC)+relative offset IF (A)<#data THEN (C) ← 1 ELSE (C) ← 0 (PC) ← (PC)+3 IF (Rr) ≠ #data r=0~7 [...]

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    DESCRIPTION OF INSTRUCTIONS 243 Mnemonic Instruction code D7 D6 D5 D4 D3 D2 D1 D0 Byte Cycle Description Page Classifi- cation Branching instructions CJNE DJNZ DJNZ JZ @Rr, #data, rel Rr, rel direct, rel rel 3 2 3 2 2 2 2 2 (PC) ← (PC)+3 IF ((Rr)) ≠ #data r=0 or 1 THEN (PC) ← (PC)+relative offset IF ((Rr))<#data r=0 or 1 THEN (C) ← 1 ELS[...]

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    MSM80C154S/83C154S/85C154HVS 244 Mnemonic Instruction code D7 D6 D5 D4 D3 D2 D1 D0 Byte Cycle Description Page Classifi- cation Branching instructions JNZ rel 2 2 (PC) ← (PC)+2 IF (A) ≠ 0 THEN (PC) ← (PC)+relative offset 01110000 R 7 R 6 R 5 R 4 R 3 R 2 R 1 R 0 JC rel 2 2 (PC) ← (PC)+2 IF (C)=1 THEN (PC) ← (PC)+relative offset 01000000 R [...]

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    DESCRIPTION OF INSTRUCTIONS 245 Mnemonic Instruction code D7 D6 D5 D4 D3 D2 D1 D0 Byte Cycle Description Page Classifi- cation External memory instructions Other instruction MOVX A, @Rr (A) ← ((Rr)) (A) ← ((DPTR)) ((Rr)) ← (A) ((DPTR)) ← (A) (PC) ← (PC)+1 1110001 r MOVX A, @DPTR 11100000 MOVX @Rr, A 1111001 r MOVX @DPTR, A 11110000 NOP 1 [...]

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    MSM80C154S/83C154S/85C154HVS 246 7.5 Detailed Description of MSM80C154S/MSM83C154S Instructions Note: “direct address” is represented as “data address” in this detailed description. 1. ACALL code address (Absolute call within 2K bytes page) A 10 A 9 A 8 10000 70 Instruction code Call address Operations Number of bytes Number of cycles Flags[...]

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    DESCRIPTION OF INSTRUCTIONS 247 2. ADD A, #data (Add immediate data) 00100100 70 Instruction code #data Operation Number of bytes Number of cycles Flags (PSW) Description Example ADD A, #07H Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 2 (A) ← (A)+#data : C AC F0 RS1 RS0 OV F1 P •• • • : : : An 8-bit immediate data va[...]

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    MSM80C154S/83C154S/85C154HVS 248 3. ADD A, @Rr (Add indirect address) 0010011 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example ADD A, @R0 Instruction code : Byte 1 (A) ← (A)+((Rr)) r=0 or 1 : C AC F0 RS1 RS0 OV F1 P •• • • : : : The data memory location contents addressed by the register r c[...]

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    DESCRIPTION OF INSTRUCTIONS 249 4. ADD A, Rr (Add register) 00101 r 2 r 1 r 0 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example ADD A, R6 Instruction code : Byte 1 (A) ← (A)+(Rr) r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P •• • • : : : The register r contents are added to the accumulator. The result i[...]

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    MSM80C154S/83C154S/85C154HVS 250 5. ADD A, data address (Add memory) 00100101 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example ADD A, P1 Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (A) ← (A)+(data address) : C AC F0 RS1 RS0 OV F1 P •• • • : : : The specifie[...]

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    DESCRIPTION OF INSTRUCTIONS 251 6. ADDC A, #data (Add carry plus immediate data to accumulator) 00110100 70 Instruction code #data Operation Number of bytes Number of cycles Flags (PSW) Description Example ADDC A, #76H Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 2 (A) ← (A)+(C)+#data : C AC F0 RS1 RS0 OV F1 P •• • • [...]

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    MSM80C154S/83C154S/85C154HVS 252 7. ADDC A, @Rr (Add carry plus indirect address to accumulator) 0011011 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example ADDC A, @R0 Instruction code : Byte 1 (A) ← (A)+(C)+((Rr)) r=0 or 1 : C AC F0 RS1 RS0 OV F1 P •• • • : : : The carry flag is added to the [...]

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    DESCRIPTION OF INSTRUCTIONS 253 8. ADD A, Rr (Add carry plus register to accumulator) 00111 r 2 r 1 r 0 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example ADDC A, R2 Instruction code : Byte 1 (A) ← (A)+(C)+(Rr) r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P •• • • : : : The carry flag is added to the accu[...]

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    MSM80C154S/83C154S/85C154HVS 254 9. ADDC A, data address (Add carry plus memory to accumulator) 00110101 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example ADDC A, 45H Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (A) ← (A)+(C)+(data address) : C AC F0 RS1 RS0 OV F1 P [...]

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    DESCRIPTION OF INSTRUCTIONS 255 10. AJMP code address (Absolute jump within 2K byte page) A 10 A 9 A 8 00001 70 Instruction code Call address Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 A 7 A 6 A 5 A 4 A 3 A 2 A 1 A 0 70 Byte 2 (PC) ← (PC)+2 (PC 0~10 ) ← A 0~10 : C AC F0 RS1 RS0 OV F1 P : After an increment ,the[...]

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    MSM80C154S/83C154S/85C154HVS 256 11. ANL A, #data (Logical AND immediate data to accumulator) 01010100 70 Instruction code #data Operation Number of bytes Number of cycles Flags (PSW) Description Example ANL A, #0AH Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 2 (A) ← (A) AND #data : C AC F0 RS1 RS0 OV F1 P • : : : The logi[...]

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    DESCRIPTION OF INSTRUCTIONS 257 12. ANL A, @Rr (Logical AND indirect address to accumulator) 0101011 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example ANL A, @R0 Instruction code : Byte 1 (A) ← (A) AND ((Rr)) r=0 or 1 : C AC F0 RS1 RS0 OV F1 P • : : : The logical AND between the accumulator content[...]

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    MSM80C154S/83C154S/85C154HVS 258 13. ANL A, Rr (Logical AND register to accumulator) 01011 r 2 r 1 r 0 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example ANL A, R5 Instruction code : Byte 1 (A) ← (A) AND (Rr) r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P • : : : The logical AND between the accumulator contents[...]

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    DESCRIPTION OF INSTRUCTIONS 259 14. ANL A, data address (Logical AND memory to accumulator) 01010101 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example ANL A, P1 Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (A) ← (A) AND (data address) : C AC F0 RS1 RS0 OV F1 P • : [...]

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    MSM80C154S/83C154S/85C154HVS 260 15. ANL C, bit address (Logical AND bit to carry flag) 10000010 70 Instruction code Bit address Operation Number of bytes Number of cycles Flags (PSW) Description Example ANL C, ACC.5 Instruction code : Byte 1 b 7 b 6 b 5 b 4 b 3 b 2 b 1 b 0 70 Byte 2 (C) ← (C) AND (bit address) : C AC F0 RS1 RS0 OV F1 P • : : :[...]

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    DESCRIPTION OF INSTRUCTIONS 261 16. ANL C,/bit address (Logical AND complement bit to carry flag) 10110000 70 Instruction code Bit address Operation Number of bytes Number of cycles Flags (PSW) Description Example ANL C,/P1.3 Instruction code : Byte 1 b 7 b 6 b 5 b 4 b 3 b 2 b 1 b 0 70 Byte 2 (C) ← (C) AND ( bit address ) : C AC F0 RS1 RS0 OV F1 [...]

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    MSM80C154S/83C154S/85C154HVS 262 17. ANL data address, #data (Logical AND immediate data to memory) 01010011 70 Instruction code Data address #data Operation Number of bytes Number of cycles Flags (PSW) Description Example ANL DPH, #0AAH Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 3 (data address) ← (data address) AND #data [...]

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    DESCRIPTION OF INSTRUCTIONS 263 18. ANL data address, A (Logical AND accumulator to memory) 01010010 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example ANL TCON, A Instruction code : Byte 1 (data address) ← (data address) AND (A) : C AC F0 RS1 RS0 OV F1 P : : : The logical AND between the a[...]

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    MSM80C154S/83C154S/85C154HVS 264 19. CJNE @Rr, #data, code address (Compare indirect address to immediate data, jump if not equal) 1011011 r 70 Instruction code #data Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 R 7 R 6 R 5 R 4 R 3 R 2 R 1 R 0 70 Byte 3 (PC) ← (PC)+3 IF ((Rr)) ≠ #data r=0 or 1 THE[...]

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    DESCRIPTION OF INSTRUCTIONS 265 Instruction code CJNE @R1, #05H, TEST Example 10110111 70 Byte 1 Register 1 00110101 70 Before execution Register 1 00110101 70 After execution : 35H 00101011 70 35H 00101011 70 1 Carry flag 0 Carry flag Program counter 15 8 0000000100011000 70 Program counter 15 8 0000000010110100 70 00000101 70 Byte 2 10011001 70 B[...]

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    MSM80C154S/83C154S/85C154HVS 266 20. CJNE A, #data, code address (Compare immediate data to accumulator, jump if not equal) 10110100 70 Instruction code #data Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 R 7 R 6 R 5 R 4 R 3 R 2 R 1 R 0 70 Byte 3 (PC) ← (PC)+3 IF (A) ≠ #data THEN (PC) ← (PC)+rela[...]

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    DESCRIPTION OF INSTRUCTIONS 267 Instruction code CJNE A, #0AH, SS1 Example 10110100 70 Byte 1 Accumulator 01010000 70 Before execution Accumulator 01010000 70 After execution : 1 Carry flag 0 Carry flag Program counter 15 8 0000000011001000 70 Program counter 15 8 0000000001100100 70 00001010 70 Byte 2 10011001 70 Byte 3 LOC 0064 00C8 00CB OBJ FF B[...]

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    MSM80C154S/83C154S/85C154HVS 268 21. CJNE A, data address, code address (Compare memory to accumulator, jump if not equal) 10110101 70 Instruction code Data address Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 R 7 R 6 R 5 R 4 R 3 R 2 R 1 R 0 70 Byte 3 (PC) ← (PC)+3 IF (A) ≠ (data address) THEN (PC[...]

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    DESCRIPTION OF INSTRUCTIONS 269 Instruction code CJNE A, 50H, NEXT Example 10110101 70 Byte 1 50H 01011110 70 Before execution 50H 01011110 70 After execution : 0 Carry flag 1 Carry flag Program counter 15 8 0001000011011100 70 Program counter 15 8 0001000100100011 70 01010000 70 Byte 2 01000100 70 Byte 3 LOC 10DC 10DF 1123 OBJ B55044 120100 14 SOU[...]

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    MSM80C154S/83C154S/85C154HVS 270 22. CJNE Rr, #data, code address (Compare immediate data to register, jump if not equal) 10111 r 2 r 1 r 0 70 Instruction code #data Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 R 7 R 6 R 5 R 4 R 3 R 2 R 1 R 0 70 Byte 3 (PC) ← (PC)+3 IF ((Rr)) ≠ #data r=0 thru 7 TH[...]

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    DESCRIPTION OF INSTRUCTIONS 271 Instruction code CJNE R4, #32H, COUNT Example 10111100 70 Byte 1 Register 4 00000001 70 Before execution Register 4 00000001 70 After execution : 1 Carry flag 1 Carry flag Program counter 15 8 0000010010000010 70 Program counter 15 8 0000010001110011 70 00110010 70 Byte 2 11101110 70 Byte 3 LOC 0473 0482 OBJ 0C BC32E[...]

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    MSM80C154S/83C154S/85C154HVS 272 23. CLR A (Clear accumulator) 11100100 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example CLR A Instruction code : Byte 1 (A) ← 0 : C AC F0 RS1 RS0 OV F1 P • : : : The accumulator is cleared to 0 and flag is updated. : 11100100 70 Byte 1 Accumulator 10110101 70 1 1 Bef[...]

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    DESCRIPTION OF INSTRUCTIONS 273 24. CLR C (Clear carry flag) 11000011 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example CLR C Instruction code : Byte 1 (C) ← 0 : C AC F0 RS1 RS0 OV F1 P • : : : The carry flag is cleared to 0. : 11000011 70 Byte 1 1 1 Before execution After execution : 1 Carry flag 0 [...]

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    MSM80C154S/83C154S/85C154HVS 274 25. CLR bit address (Clear bit) 11000010 70 Instruction code Bit address Operation Number of bytes Number of cycles Flags (PSW) Description Example CLR P1.5 Instruction code : Byte 1 b 7 b 6 b 5 b 4 b 3 b 2 b 1 b 0 70 Byte 2 (bit address) ← 0 : C AC F0 RS1 RS0 OV F1 P : : : The specified bit address content is cle[...]

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    DESCRIPTION OF INSTRUCTIONS 275 26. CPL A (Complement accumulator) 11110100 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example CPL A Instruction code : Byte 1 (A) ← ( A ) : C AC F0 RS1 RS0 OV F1 P : : : Accumulator data 0 is set to 1 and 1 is set to 0. : 11110100 70 Byte 1 Accumulator 11010101 70 1 1 Be[...]

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    MSM80C154S/83C154S/85C154HVS 276 27. CPL C (Complement carry flag) 10110011 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example CPL C Instruction code : Byte 1 (C) ← ( C ) : C AC F0 RS1 RS0 OV F1 P • : : : The carry flag is set to 1 if 0, set to 0 if 1. : 10110011 70 Byte 1 1 1 Before execution After e[...]

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    DESCRIPTION OF INSTRUCTIONS 277 28. CPL bit address (Complement bit) 10110010 70 Instruction code Bit address Operation Number of bytes Number of cycles Flags (PSW) Description Example CLR B.7 Instruction code : Byte 1 b 7 b 6 b 5 b 4 b 3 b 2 b 1 b 0 70 Byte 2 (bit address) ← ( bit address ) : C AC F0 RS1 RS0 OV F1 P : : : The specified bit addre[...]

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    MSM80C154S/83C154S/85C154HVS 278 29. DA A (Decimal adjust accumulator) 11010100 70 Instruction code Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 10 1 +6 (C) ← 1 : C AC F0 RS1 RS0 OV F1 P •• : : : The arithmetic operation result located in the accumulator following an addition between two 2-digit decimal number [...]

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    DESCRIPTION OF INSTRUCTIONS 279 Example DA A Instruction code 11010100 70 Byte 1 Accumulator 10110101 70 Before execution Accumulator 00010101 70 After execution : 0 C 1 C 0 AC 0 AC Accumulator 00110001 70 Before execution Accumulator 10010111 70 After execution 1 1 1 1 Accumulator 10011100 70 Before execution Accumulator 00000010 70 After executio[...]

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    MSM80C154S/83C154S/85C154HVS 280 30. DEC @Rr (Decrement indirect address) 0001011 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example DEC @R0 Instruction code : Byte 1 ((Rr)) ← ((Rr))–1 r=0 or 1 : C AC F0 RS1 RS0 OV F1 P : : : The contents of the data memory location addressed by the register r conte[...]

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    DESCRIPTION OF INSTRUCTIONS 281 31. DEC A (Decrement accumulator) 00010100 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example DEC A Instruction code : Byte 1 (A) ← (A)–1 : C AC F0 RS1 RS0 OV F1 P • : : : The accumulator contents are decremented by 1, and the flag is updated. : 00010100 70 Byte 1 Acc[...]

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    MSM80C154S/83C154S/85C154HVS 282 32. DEC Rr (Decrement register) 00011 r 2 r 1 r 0 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example DEC R7 Instruction code : Byte 1 (Rr) ← (Rr)–1 r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P : : : The register r contents are decremented by 1. : 00011111 70 Byte 1 Register 7 [...]

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    DESCRIPTION OF INSTRUCTIONS 283 33. DEC data address (Decrement memory) 00010101 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example DEC 5AH Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (data address) ← (data address)–1 : C AC F0 RS1 RS0 OV F1 P : : : The specified d[...]

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    MSM80C154S/83C154S/85C154HVS 284 34. DIV AB (Divide accumulator by B) 10000100 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example DIV AB(0AEH÷7H=18 ………… remainder 6H) Instruction code : Byte 1 (A) quotient ← (A)/(B) (B) remainder : C AC F0 RS1 RS0 OV F1 P •• • : : : The accumulator conten[...]

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    DESCRIPTION OF INSTRUCTIONS 285 35. DJNZ Rr, code address (Decrement register, and jump if not zero) 11011 r 2 r 1 r 0 70 Instruction code Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 R 7 R 6 R 5 R 4 R 3 R 2 R 1 R 0 70 Byte 2 (PC) ← (PC)+2 (Rr) ← (Rr)–1 r=0 thru 7 IF (Rr) ≠ 0 THEN (PC) ← (PC[...]

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    MSM80C154S/83C154S/85C154HVS 286 Instruction code DJNZ R1, LOOP Example 11011001 70 Byte 1 Register 1 00001000 70 Before execution Register 1 00000111 70 After execution : Program counter 15 8 0000000100001011 70 Program counter 15 8 0000000011111110 70 11110001 70 Byte 2 LOC 00FE 010B OBJ 2F D9F1 SOURCE LOOP:ADD A, R7 COUNT:DJNZ R1, LOOP[...]

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    DESCRIPTION OF INSTRUCTIONS 287 36. DJNZ data address, code address (Decrement memory, and jump if not zero) 11010101 70 Instruction code Data address Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 R 7 R 6 R 5 R 4 R 3 R 2 R 1 R 0 70 Byte 3 (PC) ← (PC)+3 (data address) ← (data address)–1 IF (data a[...]

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    MSM80C154S/83C154S/85C154HVS 288 Instruction code DJNZ 57H, LOOP 1 Example 11010101 70 Byte 1 57H 01101011 70 Before execution 57H 01101010 70 After execution : Program counter 15 8 0001000010010101 70 Program counter 15 8 0001000000110011 70 01010111 70 Byte 2 10011011 70 Byte 3 LOC 1033 1095 OBJ A957 D5579B SOURCE LOOP 1:MOV R1, 57H COUNT:DJNZ 57[...]

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    DESCRIPTION OF INSTRUCTIONS 289 37. INC @Rr (Increment indirect address) 0000011 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example INC @R1 Instruction code : Byte 1 ((Rr)) ← ((Rr))+1 r=0 or 1 : C AC F0 RS1 RS0 OV F1 P : : : The contents of the data memory location addressed by the register r contents[...]

  • Pagina 297

    MSM80C154S/83C154S/85C154HVS 290 38. INC A (Increment accumulator) 00000100 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example INC A Instruction code : Byte 1 (A) ← (A)+1 : C AC F0 RS1 RS0 OV F1 P • : : : The accumulator contents are incremented by 1, and the flag is updated. : 00000100 70 Byte 1 Accu[...]

  • Pagina 298

    DESCRIPTION OF INSTRUCTIONS 291 39. INC DPTR (Increment data pointer) 10100011 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example INC DPTR Instruction code : Byte 1 (DPTR) ← (DPTR)+1 : C AC F0 RS1 RS0 OV F1 P : : : 16-bit contents od the data pointer (DPH·DPL) are incremented by 1. : 10100011 70 Byte 1[...]

  • Pagina 299

    MSM80C154S/83C154S/85C154HVS 292 40. INC Rr (Increment register) 00001 r 2 r 1 r 0 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example INC R5 Instruction code : Byte 1 (Rr) ← (Rr)+1 r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P : : : The register r contents are incremented by 1. : 00001101 70 Byte 1 Register 5 10[...]

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    DESCRIPTION OF INSTRUCTIONS 293 41. INC data address (Increment memory) 00000101 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example INC P1 Instruction code Data address : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (data address) ← (data address)+1 : C AC F0 RS1 RS0 OV F1 P : : : The s[...]

  • Pagina 301

    MSM80C154S/83C154S/85C154HVS 294 42. JB bit address, code address (Jump if bit is set) 00100000 70 Instruction code Bit address Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 R 7 R 6 R 5 R 4 R 3 R 2 R 1 R 0 70 Byte 3 (PC) ← (PC)+3 IF (bit address)=1 THEN (PC) ← (PC)+relative offset : C AC F0 RS1 RS0[...]

  • Pagina 302

    DESCRIPTION OF INSTRUCTIONS 295 Instruction code JB 34.3, ENTER Example 00100000 70 Byte 1 34 0100 1000 70 Before execution 34 0100 1000 70 After execution : Program counter 15 8 0000100100000011 70 Program counter 15 8 0000100101010000 70 00010011 70 Byte 2 01001010 70 Byte 3 LOC 0903 0950 OBJ 20134A ACA0 SOURCE BITTS:JB 34.3, ENTER ENTER:MOV R4, [...]

  • Pagina 303

    MSM80C154S/83C154S/85C154HVS 296 43. JBC bit address, code address (Jump and clear if bit is set) 00010000 70 Instruction code Bit address Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 R 7 R 6 R 5 R 4 R 3 R 2 R 1 R 0 70 Byte 3 (PC) ← (PC)+3 IF (bit address)=1 THEN (bit address) ← 0 (PC) ← (PC)+re[...]

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    DESCRIPTION OF INSTRUCTIONS 297 Instruction code JBC 46.1, COUNT 4 Example 00010000 70 Byte 1 46 101010 10 70 Before execution 46 101010 00 70 After execution : Program counter 15 8 0000000100110110 70 Program counter 15 8 0000000011011100 70 01110001 70 Byte 2 10100011 70 Byte 3 LOC 00DC 0136 OBJ C281 1071A3 SOURCE COUNT 4:CLR 128.1 BTEST:JBC46.1,[...]

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    MSM80C154S/83C154S/85C154HVS 298 44. JC code address (Jump if carry is set) 01000000 70 Instruction code Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 (PC) ← (PC)+2 IF (C)=1 THEN (PC) ← (PC)+relative offset : C AC F0 RS1 RS0 OV F1 P : : : Control is shifted to a relative jump address if the carry f[...]

  • Pagina 306

    DESCRIPTION OF INSTRUCTIONS 299 Instruction code JC CARRY Example 01000000 70 Byte 1 Before execution After execution : Program counter 15 8 0001011011011110 70 Program counter 15 8 0001011011110101 70 00010101 70 Byte 2 LOC 16DC 16DE 16F5 OBJ 7110 4015 07 SOURCE CHECK:ACALL ADDR JMPC:JC CARRY CARRY:INC @R1 1 Carry flag 1 Carry flag[...]

  • Pagina 307

    MSM80C154S/83C154S/85C154HVS 300 45. JMP @A + DPTR (Jump to sum of accumulator and data pointer) 01110011 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example JMP @A+DPTR Instruction code : Byte 1 (PC) ← (A)+(DPTR) : C AC F0 RS1 RS0 OV F1 P : : : The accumulator contents are added to the data pointer con-[...]

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    DESCRIPTION OF INSTRUCTIONS 301 46. JNB bit address, code address (Jump if bit is not set) 00110000 70 Instruction code Bit address Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 R 7 R 6 R 5 R 4 R 3 R 2 R 1 R 0 70 Byte 3 (PC) ← (PC)+3 IF (bit address)=0 THEN (PC) ← (PC)+relative offset : C AC F0 RS1[...]

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    MSM80C154S/83C154S/85C154HVS 302 Instruction code JNB 37.3, EXIT Example 00110000 70 Byte 1 37 0011 0111 70 Before execution 37 0011 0111 70 After execution : Program counter 15 8 0000100000110101 70 Program counter 15 8 0000100001011010 70 00101011 70 Byte 2 00100010 70 Byte 3 LOC 0835 085A OBJ 302B22 E6 SOURCE TEST:JNB 37.3, EXIT EXIT:MOV A, @R0 [...]

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    DESCRIPTION OF INSTRUCTIONS 303 47. JNC code address (Jump if carry is not set) 01010000 70 Instruction code Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 (PC) ← (PC)+2 IF (C)=0 THEN (PC) ← (PC)+relative offset : C AC F0 RS1 RS0 OV F1 P : : : Control is shifted to a relative jump address if the car[...]

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    MSM80C154S/83C154S/85C154HVS 304 Instruction code JNC EXIT Example 01010000 70 Byte 1 Before execution After execution : Program counter 15 8 0000100000110101 70 Program counter 15 8 0000100001011001 70 00100010 70 Byte 2 LOC 0835 0859 OBJ 5022 85E0F0 SOURCE TEST:JNC EXIT EXIT:MOV B, ACC 0 Carry flag 0 Carry flag[...]

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    DESCRIPTION OF INSTRUCTIONS 305 48. JNZ code address (Jump if accumulator is not 0) 01110000 70 Instruction code Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 (PC) ← (PC)+2 IF (A) ≠ 0 THEN (PC) ← (PC)+relative offset : C AC F0 RS1 RS0 OV F1 P : : : Control is shifted to a relative jump address if[...]

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    MSM80C154S/83C154S/85C154HVS 306 Instruction code JNZ TEST Example 01110000 70 Byte 1 Before execution After execution : Program counter 15 8 0000000011111100 70 Program counter 15 8 0000000100101110 70 00110000 70 Byte 2 LOC 00FC 012E OBJ 7030 FB SOURCE CHECK:JNZ TEST TEST:MOV R3, A Accumulator 01011101 70 Accumulator 01011101 70[...]

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    DESCRIPTION OF INSTRUCTIONS 307 49. JZ code address (Jump if accumulator is not 0) 01100000 70 Instruction code Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 (PC) ← (PC)+2 IF (A)=0 THEN (PC) ← (PC)+relative offset : C AC F0 RS1 RS0 OV F1 P : : : Control is shifted to a relative jump address if the [...]

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    MSM80C154S/83C154S/85C154HVS 308 Instruction code JZ EMPTY Example 01100000 70 Byte 1 Before execution After execution : Program counter 15 8 0000000011001010 70 Program counter 15 8 0000000010011001 70 11001101 70 Byte 2 LOC 0099 00CA OBJ 04 60CD SOURCE EMPTY:INC A CHECK:JZ EMPTY Accumulator 00000000 70 Accumulator 00000000 70[...]

  • Pagina 316

    DESCRIPTION OF INSTRUCTIONS 309 50. LCALL code address (Long call) 00010010 70 Instruction code Call address Call address Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 A 15 A 14 A 13 A 12 A 11 A 10 A 9 A 8 70 Byte 2 (PC) ← (PC)+3 (SP) ← (SP)+1 ((SP)) ← (PC 0~7 ) (SP) ← (SP)+1 ((SP)) ← (PC 8~15 ) (PC 0~15 ) ?[...]

  • Pagina 317

    MSM80C154S/83C154S/85C154HVS 310 51. LJMP code address (Long jump) 00000010 70 Instruction code Jump address Jump address Operation Number of bytes Number of cycles Flags (PSW) Description : Byte 1 A 15 A 14 A 13 A 12 A 11 A 10 A 9 A 8 70 Byte 2 (PC 0~15 ) ← A 0~15 : C AC F0 RS1 RS0 OV F1 P : Jump address A 0~15 specified by operand are placed in[...]

  • Pagina 318

    DESCRIPTION OF INSTRUCTIONS 311 52. MOV @Rr, #data (Move immediate data to indirect address) 0111011 r 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV @R1, #0AAH Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 2 ((Rr)) ← #data r=0 or 1 : C AC F0 RS1 RS0 OV F1 P : : [...]

  • Pagina 319

    MSM80C154S/83C154S/85C154HVS 312 53. MOV @Rr, A (Move accumulator to indirect address) 1111011 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV @R0, A Instruction code : Byte 1 ((Rr)) ← (A) r=0 or 1 : C AC F0 RS1 RS0 OV F1 P : : : The accumulator contents are copied to the data memory location a[...]

  • Pagina 320

    DESCRIPTION OF INSTRUCTIONS 313 54. MOV @Rr, data address (Move memory to indirect address) 1010011 r 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV @R0, 0E0H Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 ((Rr)) ← (data address) r=0 or 1 : C AC F0 RS1 RS0 OV F1[...]

  • Pagina 321

    MSM80C154S/83C154S/85C154HVS 314 55. MOV A, #data (Move immediate data to accumulator) 01110100 70 Instruction code #data Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV A, #05H Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 2 (A) ← #data : C AC F0 RS1 RS0 OV F1 P • : : : An 8-bit immediate data[...]

  • Pagina 322

    DESCRIPTION OF INSTRUCTIONS 315 56. MOV A, @Rr (Move indirect address to accumulator) 1110011 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV A, @R0 Instruction code : Byte 1 (A) ← ((Rr)) r=0 or 1 : C AC F0 RS1 RS0 OV F1 P • : : : The data memory location contents addressed by the register r [...]

  • Pagina 323

    MSM80C154S/83C154S/85C154HVS 316 57. MOV A, Rr (Move register to accumulator) 11101 r 2 r 1 r 0 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV A, R6 Instruction code : Byte 1 (A) ← (Rr) r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P • : : : The register r contents are copied to the accumulator, and the [...]

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    DESCRIPTION OF INSTRUCTIONS 317 58. MOV A, data address (Move memory to accumulator) 11100101 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV A, P1 Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (A) ← (data address) : C AC F0 RS1 RS0 OV F1 P • : : : The specifi[...]

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    MSM80C154S/83C154S/85C154HVS 318 59. MOV C, bit address (Move bit to carry flag) 10100010 70 Instruction code Bit address Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV C, P3.4 Instruction code : Byte 1 b 7 b 6 b 5 b 4 b 3 b 2 b 1 b 0 70 Byte 2 (C) ← (bit address) : C AC F0 RS1 RS0 OV F1 P • : : : The specified b[...]

  • Pagina 326

    DESCRIPTION OF INSTRUCTIONS 319 60. MOV DPTR, #data (Move immediate data to data pointer) 10010000 70 Instruction code #data #data Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV DPTR, #0AF5H Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 3 (DPTR) ← #data (DPH) ← I 8~15 (DPL) ← I 0~7 : C AC F0[...]

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    MSM80C154S/83C154S/85C154HVS 320 61. MOV Rr, #data (Move immediate data to register) 01111 r 2 r 1 r 0 70 Instruction code #data Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV R5, #0AH Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 2 (Rr) ← #data r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P : : : An 8-bi[...]

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    DESCRIPTION OF INSTRUCTIONS 321 62. MOV Rr, A (Move accumulator to register) 11111 r 2 r 1 r 0 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV R1, A Instruction code : Byte 1 (Rr) ← (A) r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P : : : The accumulator contents are copied to the register r. : 11111001 70[...]

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    MSM80C154S/83C154S/85C154HVS 322 63. MOV Rr, data address (Move memory to register) 10101 r 2 r 1 r 0 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV R0, 5AH Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (Rr) ← (data address) r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P[...]

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    DESCRIPTION OF INSTRUCTIONS 323 64. MOV bit address, C (Move carry flag to bit) 10010010 70 Instruction code Bit address Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV P1.4, C Instruction code : Byte 1 b 7 b 6 b 5 b 4 b 3 b 2 b 1 b 0 70 Byte 2 (bit address) ← (C) : C AC F0 RS1 RS0 OV F1 P : : : The carry flag conte[...]

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    MSM80C154S/83C154S/85C154HVS 324 65. MOV data address, #data (Move immediate data to memory) 01110101 70 Instruction code Data address #data Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV TCON, #50H Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 3 (data address) ← #data : C AC F0 RS1 RS0 OV F1 P [...]

  • Pagina 332

    DESCRIPTION OF INSTRUCTIONS 325 66. MOV data address, @Rr (Move indirect address to memory) 1000011 r 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV ACC, @R1 Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (data address) ← ((Rr)) r=0 or 1 : C AC F0 RS1 RS0 OV F1 [...]

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    MSM80C154S/83C154S/85C154HVS 326 67. MOV data address, A (Move accumulator to memory) 11110101 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV P3, A Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (data address) ← (A) : C AC F0 RS1 RS0 OV F1 P : : : The accumulato[...]

  • Pagina 334

    DESCRIPTION OF INSTRUCTIONS 327 68. MOV data address, Rr (Move register to memory) 10001 r 2 r 1 r 0 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV 6BH, R2 Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (data address) ← (Rr) r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P [...]

  • Pagina 335

    MSM80C154S/83C154S/85C154HVS 328 69. MOV data address 1, data address 2 (Move memory to memory) 10000101 70 Instruction code Data address 2 Data address 1 Operation Number of bytes Number of cycles Flags (PSW) Description Example MOV ACC, P1 Instruction code : Byte 1 a 7 1 a 6 1 a 5 1 a 4 1 a 3 1 a 2 1 a 1 1 a 0 1 70 Byte 3 (data address 1) ← (da[...]

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    DESCRIPTION OF INSTRUCTIONS 329 70. MOVC A, @A + DPTR (Move code memory offset from data pointer to accumulator) 10010011 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example MOVC A, @A+DPTR Instruction code : Byte 1 (A) ← ((A)+(DPTR)) : C AC F0 RS1 RS0 OV F1 P • : : : The data pointer contents are adde[...]

  • Pagina 337

    MSM80C154S/83C154S/85C154HVS 330 71. MOVC A, @A + PC (Move code memory offset from program counter to accumulator) 10000011 70 Instruction code Operations Number of bytes Number of cycles Flags (PSW) Description Example MOVC A, @A+PC Instruction code : Byte 1 (PC) ← (PC)+1 (A) ← ((A)+(PC)) : C AC F0 RS1 RS0 OV F1 P • : : : The program counter[...]

  • Pagina 338

    DESCRIPTION OF INSTRUCTIONS 331 72. MOVX @DPTR, A (Move accumulator to external memory addressed by data pointer) 11110000 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example MOVX @DPTR, A Instruction code : Byte 1 ((DPTR)) ← (A) : C AC F0 RS1 RS0 OV F1 P : : : The accumulator contents are stored in exte[...]

  • Pagina 339

    MSM80C154S/83C154S/85C154HVS 332 73. MOVX @Rr, A (Move accumulator to external memory addressed by register) 1111001 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example MOVX @R0, A Instruction code : Byte 1 ((Rr)) ← (A) r=0 or 1 : C AC F0 RS1 RS0 OV F1 P : : : The accumulator contents are stored in ext[...]

  • Pagina 340

    DESCRIPTION OF INSTRUCTIONS 333 74. MOVX A, @DPTR (Move external memory addressed by data pointer to accumulator) 11100000 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example MOVX A, @DPTR Instruction code : Byte 1 (A) ← ((DPTR)) : C AC F0 RS1 RS0 OV F1 P • : : : External data memory (RAM) contents add[...]

  • Pagina 341

    MSM80C154S/83C154S/85C154HVS 334 75. MOVX A, @Rr (Move external memory addressed by register to accumulator) 1110001 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example MOVX A, @R1 Instruction code : Byte 1 (A) ← ((Rr)) r=0 or 1 : C AC F0 RS1 RS0 OV F1 P • : : : External data memory (RAM) contents ad[...]

  • Pagina 342

    DESCRIPTION OF INSTRUCTIONS 335 76. MUL AB (Multiply accumulator by B) 10100100 70 Instruction code Operations Number of bytes Number of cycles Flags (PSW) Description Example MUL AB(6AH × 15H=8B2H) Instruction code : Byte 1 (A) 0~7 ← (A) × (B) (B) 8~15 : C AC F0 RS1 RS0 OV F1 P •• • : : : The accumulator contents are multiplied by the ar[...]

  • Pagina 343

    MSM80C154S/83C154S/85C154HVS 336 77. NOP (No operation) 00000000 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description : Byte 1 (PC) ← (PC)+1 : C AC F0 RS1 RS0 OV F1 P : : : The program counter is incremented by 1 without any other change in the CPU. Control is shifted to the next instruction. : 1 1[...]

  • Pagina 344

    DESCRIPTION OF INSTRUCTIONS 337 78. ORL A, #data (Logical OR immediate data to accumulator) 01000100 70 Instruction code #data Operation Number of bytes Number of cycles Flags (PSW) Description Example ORL A, #5FH Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 2 (A) ← (A) OR #data : C AC F0 RS1 RS0 OV F1 P • : : : The logical[...]

  • Pagina 345

    MSM80C154S/83C154S/85C154HVS 338 79. ORL A, @Rr (Logical OR indirect address to accumulator) 0100011 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example ORL A, @R0 Instruction code : Byte 1 (A) ← (A) OR ((Rr)) r=0 or 1 : C AC F0 RS1 RS0 OV F1 P • : : : The logical OR between the accumulator contents [...]

  • Pagina 346

    DESCRIPTION OF INSTRUCTIONS 339 80. ORL A, Rr (Logical OR register to accumulator) 01001 r 2 r 1 r 0 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example ORL A, R5 Instruction code : Byte 1 (A) ← (A) OR (Rr) r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P • : : : The logical OR between the accumulator contents and[...]

  • Pagina 347

    MSM80C154S/83C154S/85C154HVS 340 81. ORL A, data address (Logical OR memory to accumulator) 01000101 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example ORL A, 33H Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (A) ← (A) OR (data address) : C AC F0 RS1 RS0 OV F1 P • : [...]

  • Pagina 348

    DESCRIPTION OF INSTRUCTIONS 341 82. ORL C, bit address (Logical OR bit to carry flag) 01110010 70 Instruction code Bit address Operation Number of bytes Number of cycles Flags (PSW) Description Example ORL C, ACC.6 Instruction code : Byte 1 b 7 b 6 b 5 b 4 b 3 b 2 b 1 b 0 70 Byte 2 (C) ← (C) OR (bit address) : C AC F0 RS1 RS0 OV F1 P • : : : Th[...]

  • Pagina 349

    MSM80C154S/83C154S/85C154HVS 342 83. ORL C,/bit address (Logical OR complement of bit to carry flag) 10100000 70 Instruction code Bit address Operation Number of bytes Number of cycles Flags (PSW) Description Example ORL C,/25H.5 Instruction code : Byte 1 b 7 b 6 b 5 b 4 b 3 b 2 b 1 b 0 70 Byte 2 (C) ← (C) OR ( bit address ) : C AC F0 RS1 RS0 OV [...]

  • Pagina 350

    DESCRIPTION OF INSTRUCTIONS 343 84. ORL data address, #data (Logical OR immediate data to memory) 01000011 70 Instruction code Data address #data Operation Number of bytes Number of cycles Flags (PSW) Description Example ORL 55H, #11H Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 3 (data address) ← (data address) OR #data : C [...]

  • Pagina 351

    MSM80C154S/83C154S/85C154HVS 344 85. ORL data address, A (Logical OR accumulator to memory) 01000010 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example ORL 50H, A Instruction code : Byte 1 (data address) ← (data address) OR (A) : C AC F0 RS1 RS0 OV F1 P : : : The logical OR between the accu[...]

  • Pagina 352

    DESCRIPTION OF INSTRUCTIONS 345 86. POP data address (Pop stack to memory) 11010000 70 Instruction code Data address Operations Number of bytes Number of cycles Flags (PSW) Description Example POP PSW:No change to parity bit. Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (data address) ← ((SP)) (SP) ← (SP)–1 : C AC F0 RS[...]

  • Pagina 353

    MSM80C154S/83C154S/85C154HVS 346 87. PUSH data address (Push memory onto stack) 11000000 70 Instruction code Data address Operations Number of bytes Number of cycles Flags (PSW) Description Example PUSH P1 Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (SP) ← (SP)+1 ((SP)) ← (data address) : C AC F0 RS1 RS0 OV F1 P : : : Th[...]

  • Pagina 354

    DESCRIPTION OF INSTRUCTIONS 347 88. RET (Return from subroutine, non interrupt) 00100010 70 Instruction code Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 (PC 8~15 ) ← ((SP)) (SP) ← (SP)–1 (PC 0~7 ) ← ((SP)) (SP) ← (SP)–1 : C AC F0 RS1 RS0 OV F1 P : : : The stack contents addressed by the stack pointer are[...]

  • Pagina 355

    MSM80C154S/83C154S/85C154HVS 348 89. RETI (Return from interrupt routine) 00110010 70 Instruction code Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 (PC 8~15 ) ← ((SP)) (SP) ← (SP)–1 (PC 0~7 ) ← ((SP)) (SP) ← (SP)–1 *INTERRUPT ENABLE : C AC F0 RS1 RS0 OV F1 P : : : This return instruction functions as an i[...]

  • Pagina 356

    DESCRIPTION OF INSTRUCTIONS 349 90. RL A (Rotate accumulator left) 00100011 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example RL A Instruction code : Byte 1 : C AC F0 RS1 RS0 OV F1 P : : : All accumulator bits are shifted by one bit to the left. The MSB (bit 7) is shifted to the LSB bit position (bit 0).[...]

  • Pagina 357

    MSM80C154S/83C154S/85C154HVS 350 91. RLC A (Rotate accumulator and carry flag left) 00110011 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example RLC A Instruction code : Byte 1 : C AC F0 RS1 RS0 OV F1 P •• : : : The accumulator and the carry flag are connected, and all bits are shifted by one bit to th[...]

  • Pagina 358

    DESCRIPTION OF INSTRUCTIONS 351 92. RR A (Rotate accumulator right) 00000011 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example RR A Instruction code : Byte 1 : C AC F0 RS1 RS0 OV F1 P : : : All accumulator bits are shifted by one bit to the right. The LSB (bit 0) is shifted to the MSB bit position (bit 7[...]

  • Pagina 359

    MSM80C154S/83C154S/85C154HVS 352 93. RRC A (Rotate accumulator and carry flag right) 00010011 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example RRC A Instruction code : Byte 1 : C AC F0 RS1 RS0 OV F1 P •• : : : The accumulator and the carry flag are connected, and all bits are shifted by one bit to t[...]

  • Pagina 360

    DESCRIPTION OF INSTRUCTIONS 353 94. SETB C (Set carry flag) 11010011 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example SETB C Instruction code : Byte 1 (C) ← 1 : C AC F0 RS1 RS0 OV F1 P • : : : The carry flag is cleared to 1. : 11010011 70 Byte 1 1 1 Before execution After execution : 0 Carry flag 1 [...]

  • Pagina 361

    MSM80C154S/83C154S/85C154HVS 354 95. SETB bit address (Set bit) 11010010 70 Instruction code Bit address Operation Number of bytes Number of cycles Flags (PSW) Description Example SETB IE.7 Instruction code : Byte 1 b 7 b 6 b 5 b 4 b 3 b 2 b 1 b 0 70 Byte 2 (bit address) ← 1 : C AC F0 RS1 RS0 OV F1 P : : : The specified bit address content is set[...]

  • Pagina 362

    DESCRIPTION OF INSTRUCTIONS 355 96. SJMP code address (Short jump) 10000000 70 Instruction code Relative offset Operations Number of bytes Number of cycles Flags (PSW) Description : Byte 1 (PC) ← (PC)+2 (PC) ← (PC)+relative offset : C AC F0 RS1 RS0 OV F1 P : : : Relative offset jump data is added/subtracted to/from the program counter contents [...]

  • Pagina 363

    MSM80C154S/83C154S/85C154HVS 356 Instruction code SJMP CHECK Example 10000000 70 Byte 1 Before execution After execution : Program counter 15 8 0000000100010001 70 Program counter 15 8 0000000100100011 70 00010000 70 Byte 2 LOC 0111 0123 OBJ 8010 33 SOURCE SJUMP:SJMP CHECK CHECK:RLC A[...]

  • Pagina 364

    DESCRIPTION OF INSTRUCTIONS 357 97. SUBB A, #data (Substract immediate data from accumulator with borrow) 10010100 70 Instruction code #data Operation Number of bytes Number of cycles Flags (PSW) Description Example SUBB A, #05H Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 2 (A) ← (A)–((C)+#data) : C AC F0 RS1 RS0 OV F1 P ?[...]

  • Pagina 365

    MSM80C154S/83C154S/85C154HVS 358 98. SUBB A, @Rr (Substract indirect address from accumulator with borrow) 1001011 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example SUBB A, @R0 Instruction code : Byte 1 (A) ← (A)–((C)+((Rr))) r=0 or 1 : C AC F0 RS1 RS0 OV F1 P •• • • : : : The carry flag co[...]

  • Pagina 366

    DESCRIPTION OF INSTRUCTIONS 359 99. SUBB A, Rr (Substract register from accumulator with borrow) 10011 r 2 r 1 r 0 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example SUBB A, R7 Instruction code : Byte 1 (A) ← (A)–((C)+(Rr)) : C AC F0 RS1 RS0 OV F1 P •• • • : : : The carry flag content and the [...]

  • Pagina 367

    MSM80C154S/83C154S/85C154HVS 360 100. SUBB A, data address (Substract memory from accumulator with borrow) 10010100 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example SUBB A, DPH Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (A) ← (A)–((C)+(data address)) : C AC F0 R[...]

  • Pagina 368

    DESCRIPTION OF INSTRUCTIONS 361 101. SWAP A (Exchange nibble in accumulator) 11000100 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example SWAP A Instruction code : Byte 1 (A 4~7 ) ← → (A 0~3 ) : C AC F0 RS1 RS0 OV F1 P : : : The contents of the four higher order bits (4 thru 7) of the accumulator are e[...]

  • Pagina 369

    MSM80C154S/83C154S/85C154HVS 362 102. XCH A, @Rr (Exchange indirect address with accumulator) 1100011 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example XCH A, @R0 Instruction code : Byte 1 (A) ← → ((Rr)) r=0 or 1 : C AC F0 RS1 RS0 OV F1 P • : : : The accumulator contents are exchanged with the da[...]

  • Pagina 370

    DESCRIPTION OF INSTRUCTIONS 363 103. XCH A, Rr (Exchange register with accumulator) 11001 r 2 r 1 r 0 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example XCH A, R5 Instruction code : Byte 1 (A) ← → (Rr) r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P • : : : The accumulator contents are exchanged with the regis[...]

  • Pagina 371

    MSM80C154S/83C154S/85C154HVS 364 104. XCH A, data address (Exchange memory with accumulator) 11000101 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example XCH A, 7AH Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (A) ← → (data address) : C AC F0 RS1 RS0 OV F1 P • : : [...]

  • Pagina 372

    DESCRIPTION OF INSTRUCTIONS 365 105. XCHD A, @Rr (Exchange low nibbles of indirect address with accumulator) 1101011 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example XCHD A, @R0 Instruction code : Byte 1 (A 0~3 ) ← → ((Rr 0~3 )) r=0 or 1 : C AC F0 RS1 RS0 OV F1 P • : : : The lower order bits (0 [...]

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    MSM80C154S/83C154S/85C154HVS 366 106. XRL A, #data (Logical exclusive OR immediate data to accumulator) 01100100 70 Instruction code #data Operation Number of bytes Number of cycles Flags (PSW) Description Example XRL A, #15H Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 2 (A) ← (A) XOR #data : C AC F0 RS1 RS0 OV F1 P • : : [...]

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    DESCRIPTION OF INSTRUCTIONS 367 107. XRL A, @Rr (Logical exclusive OR indirect address to accumulator) 0110011 r 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example XRL A, @R1 Instruction code : Byte 1 (A) ← (A) XOR ((Rr)) r=0 or 1 : C AC F0 RS1 RS0 OV F1 P • : : : The exclusive OR operation is execute[...]

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    MSM80C154S/83C154S/85C154HVS 368 108. XRL A, Rr (Logical exclusive OR register to accumulator) 01101 r 2 r 1 r 0 70 Instruction code Operation Number of bytes Number of cycles Flags (PSW) Description Example XRL A, R3 Instruction code : Byte 1 (A) ← (A) XOR (Rr) r=0 thru 7 : C AC F0 RS1 RS0 OV F1 P • : : : The exclusive OR between the accumulat[...]

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    DESCRIPTION OF INSTRUCTIONS 369 109. XRL A, data address (Logical exclusive OR memory to accumulator) 01100101 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example XRL A, 70H Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (A) ← (A) XOR (data address) : C AC F0 RS1 RS0 OV [...]

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    MSM80C154S/83C154S/85C154HVS 370 110. XRL data address, #data (Logical exclusive OR immediate data to memory) 01100011 70 Instruction code Data address #data Operation Number of bytes Number of cycles Flags (PSW) Description Example XRL ACC, #5AH Instruction code : Byte 1 I 7 I 6 I 5 I 4 I 3 I 2 I 1 I 0 70 Byte 3 (data address) ← (data address) X[...]

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    DESCRIPTION OF INSTRUCTIONS 371 111. XRL data address, A (Logical exclusive OR accumulator to memory) 01100010 70 Instruction code Data address Operation Number of bytes Number of cycles Flags (PSW) Description Example XRL 20H, A Instruction code : Byte 1 a 7 a 6 a 5 a 4 a 3 a 2 a 1 a 0 70 Byte 2 (data address) ← (data address) XOR (A) : C AC F0 [...]